The dynamics of Brazilian protozoology over the past century

Elias, M Carolina; Floeter-Winter, Lucile M; Mena-Chalco, Jesus P

doi:10.1590/0074-02760150386

Abstract

Brazilian scientists have been contributing to the protozoology field for more than 100 years with important discoveries of new species such asTrypanosoma cruzi and Leishmania spp. In this work, we used a Brazilian thesis database (Coordination for the Improvement of Higher Education Personnel) covering the period from 1987-2011 to identify researchers who contributed substantially to protozoology. We selected 248 advisors by filtering to obtain researchers who supervised at least 10 theses. Based on a computational analysis of the thesis databases, we found students who were supervised by these scientists. A computational procedure was developed to determine the advisors’ scientific ancestors using the Lattes Platform. These analyses provided a list of 1,997 researchers who were inspected through Lattes CV examination and allowed the identification of the pioneers of Brazilian protozoology. Moreover, we investigated the areas in which researchers who earned PhDs in protozoology are now working. We found that 68.4% of them are still in protozoology, while 16.7% have migrated to other fields. We observed that support for protozoology by national or international agencies is clearly correlated with the increase of scientists in the field. Finally, we described the academic genealogy of Brazilian protozoology by formalising the “forest” of Brazilian scientists involved in the study of protozoa and their vectors over the past century.

protozoology; pioneers; academic genealogy; scientific mapping method

The last decade of the XIX century is considered to be the period in which experimental protozoology began (Calkins 1911Calkins GN 1911. The scope of protozoology.Science34: 129-138.). At that time, protozoa were suspected of being the causative agents of only two human diseases: dysentery and malaria (Calkins 1911Calkins GN 1911. The scope of protozoology.Science34: 129-138.). Currently, protozoan parasites are recognised as the causative agents of some of most important human illnesses. For instance, amebiasis is the second leading cause of death due to parasitic diseases worldwide and causes approximately 40-100,000 deaths per year (Moraes et al. 2015Moraes LCA, França EL, Pessoa RS, Fagundes DLG, Hernandes MG, Ribeiro VP, Gomes MA, Honório-França C 2015. The effect of INF-g and TGF-b in the functional activity of mononuclear cells in the presence ofEntamoeba histolytica. Parasit Vectors8: 413.). Approximately 6.5 million people are estimated to be infected with Trypanosoma cruzi, 1,300,000 new cases of leishmaniasis occur every year, and 214 million new cases of malaria have occurred in 2015 alone. Toxoplasmosis and giardiasis are also diseases caused by protozoa, both of which represent significant public health threats (who.int). These are examples of protozoa that are of medical interest and do not include protozoa of veterinary interest or free-living protozoa, which may be important environmental markers.

Therefore, protozoology has become a unique field of study, and an impressive amount of work has gone into detailing the biological aspects of this subject. Indeed, the study of protozoa has rapidly evolved from the molecular characterisation of eukaryotes through host-parasite interactions and ecoepidemiological aspects to therapeutic interventions. Several important mechanisms were first described in protozoa, such as nonconventional RNA polymerase II promoter sites (Clayton 2002Clayton CE 2002. Life without transcriptional control? From fly to man and back again. Embo J 21: 1881-1888.), trans-splicing (Mayer & Floeter-Winter 2012Mayer MG, Floeter-Winter LM 2012. Identification of SL additiontrans-splicing acceptor sites in the internal trasncribed spacer I region of pre-rRNA in Leishmania (Leishmania) amazonensis. Mem Inst Oswaldo Cruz107: 1070-1072.) and RNA editing (Simpson et al. 2006)Simpson AG, Stevens JR, Lukes J 2006. The evolution and diversity of kinetoplastid flagellates. Trends Parasitol 22: 168-174.. Some of these findings have been highly influential in other medical and biological fields, such as the discovery of telomeres protecting chromosomes in Tetrahymena (Blackburn & Gall 1978)Blackburn EH, Gall JG 1978. Tandemly repeated sequence at the termini of the extrachromosomal ribosomal RNA genes inTetrahymena. J Mol Biol120: 33-53., the understanding of glycosylphosphatidylinositol protein anchor structures (Ferguson et al. 1985Ferguson MA, Haldar K, Cross GA 1985. Trypanosoma brucei variant surface glycoprotein has a sn-1,2-dimyristyl glycerol membrane anchor at its COOH terminus. J Biol Chem260: 4963-4968., Ferguson 1999)Ferguson MA 1999. The structure, biosynthesis, and function of glycosylphosphatidylinositol anchors, and the contribution of trypanosome research. J Cell Sci112: 2799-2809., and the delineation of the respective roles of the T-helper (Th)1 and Th2 lymphocyte subsets against infectious agents in studies using Leishmania major-infected mice (Heinzel et al. 1989)Heinzel FP, Sadick MD, Holaday BJ, Coffman RL, Locksley RM 1989. Reciprocal expression of interferon gamma of interleukin 4 during the resolution or progression of murine leishmaniasis. Evidence for expansion of distinct helper T-cell subsets. J Exp Med169: 59-72..

In Brazil, where some protozoan infections are endemic, these aetiological agents and their vectors have attracted considerable interest from researchers and students. A few “founding fathers” (pioneers) of this field of science have nurtured later generations of protozoologists, resulting in the development of a solid network of 100 years of scientists.

The evolution of science is the pillar that provides a solid foundation for the development of society by creating the means to face the challenges ahead (Cordova et al. 2015Cordova KE, Furukawa H, Yaghi OM 2015. The development of global science. ACS Cent Sci1: 18-23.). The study of the origin of a scientific area and the identification of the motives behind its development in new disciplines provide important contributions to the understanding of future needs. This academic genealogy allows the development of qualifying studies based on the training of new researchers.

Academic genealogy was defined by Sugimoto (2014)Sugimoto CR 2014. Academic genealogy. In B Cronin, CR Sugimoto (eds.), Beyond bibliometrics: harnessing multidimensional indicators of scholarly impact, MIT Press, Cambridge, p. 365-382.as a quantitative study of the intellectual heritage perpetuated through academic orientation relationships among professors (i.e., mentors or supervisors) and their students. Various questions can be answered by building an academic genealogy. Sugimoto (2014)Sugimoto CR 2014. Academic genealogy. In B Cronin, CR Sugimoto (eds.), Beyond bibliometrics: harnessing multidimensional indicators of scholarly impact, MIT Press, Cambridge, p. 365-382. proposed five types of academic genealogies: honorific, egotistical, historical, paradigmatic, and analytical. These categories are not mutually exclusive, and most academic genealogies can be classified into at least two of these types.

In this work, we followed the development of protozoology in Brazil using a historical and paradigmatic approach. Systematic data collection was performed through the analysis of formal thesis orientation and was organised to create a chain of mentorships, resulting in the construction of our academic genealogy.

MATERIALS AND METHODS

In this work, the identification of researchers associated with protozoology who influenced (supervised) other researchers over a 100 year timespan was performed through seven processes (Fig. 1). The methodology was based on the analysis of two sources of Brazilian academic information that allowed the tracing of scholarly interactions among researchers.

Fig. 1
: diagram of the tracking of Brazilian protozoologists. Each block represents a process and each arrow represents the information flow between processes.

Process 1 - Identification of dissertations and theses related to protozoology - A local repository extracted from the Coordination for the Improvement of Higher Education Personnel (CAPES) thesis database (Mena-Chalco & Rocha 2014Mena-Chalco JP, Rocha V 2014. Caracterização do banco de teses e dissertações da CAPES. In 4º Encontro Brasileiro de Bibliometria e Cientometria, 14-16 de maio de 2014, Recife, 11 pp.) was used in this process. We identified 10,456 dissertations or theses with at least one descriptor related to protozoology (Supplementary ^{Table I} Supplementary data TABLE I Descriptors used to screen theses on Coordination for the Improvement of Higher Education Personnel database ). This quantity represented 1.7% of the 607,389 dissertations or theses registered in the local repository.

Process 2 - Identification of supervisors of Masters and PhD students in protozoology - In this process, we extracted all supervisors’ names from the dissertations/theses identified in process 1. The process handled incomplete or similar names using approximate string matching. Two names were considered the same/similar if the Levenshtein distance (Levenshtein 1966Levenshtein VI 1966. Binary codes capable of correcting deletions, insertions, and reversals. Soviet Physics-Doklady10: 707-710.) between them was equal to 2. This process allowed us to identify 4,176 researchers related to the protozoology field.

Process 3 - Identification of representative protozoologists in terms of the quantity of supervisions registered in the CAPES thesis database - In this process, researchers who supervised at least 10 projects were selected to generate a list of 248 supervisors (6% of 4,176 researchers). This threshold was considered suitable for manual inspection. Supplementary ^{Table II} TABLE II Scientists that supervised at least 10 theses/dissertations containing at least one of the 60 descriptors present on Supplementary Table I source: Coordination for the Improvement of Higher Education Personnel database in the period from 1987-2011. presents the complete list of names obtained through this process.

Process 4 - Identification of ancestors of the representative protozoologists - This process was performed recursively for each supervisor identified in the Lattes Platform. First, the name of the supervisor was identified and associated with its Lattes CV. Then, the same approach was undertaken for the supervisors of the supervisors until the inability to identify a new supervisor was reached. We identified 445 researchers as the ancestors of the 248 representative protozoologists.

Process 5 - Identification of the descendants of the representative protozoologists - This process was accomplished by selecting the PhD students (process 1) who were supervised by the researchers obtained in process 3. We identified 1,335 direct descendants from the group of 248 representative protozoologists.

Process 6 - Construction of a scientist network - In this process, the researchers identified in processes 3, 4 and 5 were used to generate a supervisor network (i.e., a directed graph where each node represented a researcher, and the edge represented the relationship between 2 researchers). Duplicated names were processed manually. A list of 1,997 complete names was generated as the result of this process (Supplementary ^{Table III} TABLE III Classification of names according to diagram in Fig. 3A a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field. ).

Process 7 - Classification of protozoologists - This process was performed by manual inspection of each researcher identified in the previous process. Information from the protozoology field was associated with each of the 1,997 researchers using the Lattes Platform and academic repositories.

RESULTS

Identification of scientists actively working in protozoology - This work aims to understand the past and present of Brazilian protozoology and the migration of scientists from protozoology to other fields and from other fields to protozoology. Academic dissertations and theses are an important source of information concerning the growth and evolution of science (Andersen & Hammarfelt 2011Andersen JP, Hammarfelt B 2011. Price revisited: on the growth of dissertations in eight research fields. Scientometrics88: 371-383.). Therefore, we accessed a data collection containing most of the Brazilian protozoologists from the CAPES database combined with the Lattes examination. By searching for the supervisors of actively working protozoologists, the supervisors of these supervisors, and so on, we identified the pioneers of this field in Brazil. Similarly, by searching for students trained by these actively working protozoologists, we identified other people currently working in the field. To establish the names of actively working protozoologists to nucleate our search, we prepared a set of 60 words (descriptors) (Supplementary ^{Table I} Supplementary data TABLE I Descriptors used to screen theses on Coordination for the Improvement of Higher Education Personnel database ) for use as keywords to screen theses (Masters or PhD) present in the local CAPES thesis database, which contained all theses completed in Brazil from 1987-2011 (Mena-Chalco & Rocha 2014)Mena-Chalco JP, Rocha V 2014. Caracterização do banco de teses e dissertações da CAPES. In 4º Encontro Brasileiro de Bibliometria e Cientometria, 14-16 de maio de 2014, Recife, 11 pp.. A total of 10,456 Masters or PhD theses contained at least one such descriptor. This number corresponded to 1.7% of the total theses presented in the same period throughout all fields. A total of 4,176 researchers supervised these 10,456 dissertations/theses. As expected, the number of scientists diminished when we increased the number of works supervised per researcher (Fig. 2). For operational reasons, it might not be possible to analyse in detail all the 4,176 researchers (advisors) and the relevant factors considered in the adopted methodology. Therefore, only researchers with at least 10 dissertations/theses supervised in the field of protozoology were considered in our study (248 scientists) (Supplementary ^{Table II} TABLE II Scientists that supervised at least 10 theses/dissertations containing at least one of the 60 descriptors present on Supplementary Table I source: Coordination for the Improvement of Higher Education Personnel database in the period from 1987-2011. ). With a threshold of five or two dissertations, for instance, the number of researchers increases by 276% (689 researchers) or 745% (1,864 researchers), respectively. With the threshold adopted, important pioneers in the field of protozoology are included in the analyses, but we recognise that this empirical value might penalise early career researchers. However, we believe that this arbitrarily selected threshold of 10 dissertations/theses was appropriate to define a selected group of representative researchers. A total of 36% of these researchers are or were members of the Brazilian Society of Protozoology in the period between 2000-2015.

Fig. 2
: relationship between the number of supervisors and number of theses generated from 1987-2011 containing at least one descriptor. Supplementary Table I containing 60 descriptors was used to screen the Coordination for the Improvement of Higher Education Personnel database. The graph indicates how many scientists supervised a different number of theses containing at least one descriptor as a keyword.

Identification of Brazilian protozoologists - We used the complete list of names in Supplementary ^{Table II} TABLE II Scientists that supervised at least 10 theses/dissertations containing at least one of the 60 descriptors present on Supplementary Table I source: Coordination for the Improvement of Higher Education Personnel database in the period from 1987-2011. as a starting point to search for the people supervised by these people and vice versa (i.e., scientists who supervised these people). Using automated analysis of the local CAPES thesis database, we found students whom these researchers supervised (descendants). We did not search for students of these students because some of them were still settling, which could compromise our analysis. Based on the automated analysis of their Lattes CVs, we could also follow the advisors’ ancestors by searching for their supervisors and the supervisors of these supervisors available on the Lattes CV database (Fig. 1). As shown below, the analyses also allowed the identification of Brazilian supervisors who worked outside of protozoology and supervisors that were from other countries; thus, we could identify the seeds of Brazilian protozoology. These analyses provided a list of 1,997 names that were manually inspected through the Lattes CV examination, following the pathway shown inFig. 3A. We used the following criteria to establish that a researcher is/was working in the field of protozoology. Researchers studying the biology of protozoa or protozoa-host interaction were considered protozoologists. Additionally, scientists investigating protozoa vectors were considered protozoologists. In contrast, researchers working with protozoa but investigating the clinical aspects of diseases (e.g., mostly ophthalmologists, dermatologists, and cardiologists who study diseases caused by protozoa) were not considered protozoologists. From the total of 1,997 names found, some were not included in the Lattes database. This discrepancy might have occurred for four different reasons: (i) misspelling of names, (ii) people who are no longer in science, (iii) foreign supervisors, and (iv) people who worked in protozoology before the Lattes CV was created. To include this last group in our analysis, we searched for these people in the CAPES database or in public repositories to identify their ancestors and the field in which they worked. To include supervisors from other countries, we searched for these people in PubMed to verify the field in which they work/worked. Finally, 10.86% of the 1,997 names could not be found in either the Lattes Platform, CAPES database, or public repositories and were removed from the forward analyses. These analyses allowed the classification of researchers into five different categories: (a) scientists who are working or previously worked in protozoology in Brazil, (b) scientists working in protozoology outside of Brazil who were advisors of Brazilians, (c) scientists who did not work in protozoology during their PhD and did not establish a research interest in this field but were advisors of scientists who migrated to protozoology, (d) people who obtained their PhD in protozoology but were now involved in activities other than science, and (e) scientists who developed their PhD in protozoology but established a research interest in another field (Supplementary ^{Table III} TABLE III Classification of names according to diagram in Fig. 3A a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field. ). The frequency of each group is presented in Fig. 3B. Based on the data, 907 names were identified as Brazilian protozoologists (classified as group a).

Fig. 3
: classification of scientists according to Lattes CV. A: pathway followed during inspection with Lattes CV; B: frequency of each category described in A; a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field.

Identification of Brazilian protozoology pioneers - To identify researchers who were Brazilian protozoology pioneers, we first assumed that people who were awarded a PhD in protozoology in Brazil were not pioneers but that the pioneers would be their advisors. Therefore, we concluded that the pioneers were among the scientists who were awarded PhD degrees in other fields and then migrated to protozoology or people who were awarded PhDs in protozoology outside Brazil and then came to our country to establish a group here. Among the researchers classified as group a (Brazilian protozoologists), we manually searched the Lattes CV and the CAPES database for ones who were (766) and were not (141) awarded a PhD in protozoology (Fig. 4, Supplementary ^{Table IV} TABLE IV Classification of names that developed (1) or not (2) PhD in protozoology bolded names: persons who developed PhD in protozoology having as supervisor a nonprotozoologist. ). Additionally, we searched the Lattes CV for researchers who were awarded a PhD in protozoology outside Brazil (15) (Supplementary ^{Table V} TABLE V Year that persons who did not develop PhD in protozoology published in this field a: the year that scientist published his first paper in Brazil after his PhD; bolded names: persons who did develop PhD in protozoology outside Brazil. , in bold). Then, we determined in what year these researchers who did not receive a PhD in protozoology (141 names) or who received a PhD outside Brazil (15 names; a total of 156 names) established a protozoology group in Brazil. For scientists who arrived from other fields, we searched the Lattes CV for the year of their first paper published in protozoology (Supplementary ^{Table V} TABLE V Year that persons who did not develop PhD in protozoology published in this field a: the year that scientist published his first paper in Brazil after his PhD; bolded names: persons who did develop PhD in protozoology outside Brazil. ). For scientists who received their PhD outside of Brazil, we searched the Lattes CV for the year in which they published their first paper after their PhD from a position in Brazil (Supplementary ^{Table V} TABLE V Year that persons who did not develop PhD in protozoology published in this field a: the year that scientist published his first paper in Brazil after his PhD; bolded names: persons who did develop PhD in protozoology outside Brazil. , in bold). Carlos Chagas’s paper describing T. cruzi was not found in PubMed but was considered due to its relevancy. Using this date as the year the scientist entered Brazilian protozoology, we plotted a graph of this incoming year for each of the 156 scientists who arrived in protozoology (Fig. 5A). Additionally, we plotted a graph showing the frequency of this influx according to the year of migration (Fig. 5B). From both analyses, it was clear that there were three waves of immigration into Brazilian protozoology: (i) up to and including 1974, (ii) between 1978-1993, and (iii) between 1998-2013. However, the drop observed after 2013 might be artificial because the collection of data is recent. Thus, we concluded that the pioneers (i.e., founders or precursors) of Brazilian protozoology were the 20 scientists who migrated into the field up to 1974: Carlos Chagas, Samuel Pessoa, Hertha Meyer, Zigman Brener, Wladimir Lobato Paraense, Leonidas Deane, Maria von Paumgartten Deane, Amilcar Viana Martins, José Rodrigues da Silva, Washington Luiz Tafuri, Erney Felicio Plessmann de Camargo, Jayme Neves, Aluízio Prata, Thales de Brito, Astolpho Ferraz de Siqueira, Jeffrey Jon Shaw, Mario Endsfeldez Camargo, Isaac Roitman, Raymundo Martins de Castro, and Walter Colli.

Fig. 4
: analysis of fields where scientists classified as developed their PhD. Scientists classified in category “PhD in protozoology” were divided into those who developed and those who did not develop PhDs in protozoology.

Fig. 5
: incoming scientists into protozoology. A: the graph shows the year in which each researcher who did not develop a PhD in protozoology published their first paper in this field. Red dots indicate the year that scientists who developed a PhD in protozoology outside of Brazil published their first paper in Brazil after their PhD; B: frequency of scientists immigrating into Brazilian protozoology according to the year of arrival.

Migration of protozoology into Brazilian science - We also investigated the immigration and emigration of scientists to and from Brazilian protozoology. A total of 17.1% of the studied researchers immigrated into protozoology, based on the number of people who entered protozoology from other fields and arrived from protozoology outside of Brazil (156 names/907 total). Researchers who stayed in protozoology after their PhD corresponded to 68.4% of individuals, based on the 770 protozoologists who received a PhD in protozoology and were still acting as protozoologists, those who received a PhD in protozoology and were involved in other activities but still involved in science [group d: 167 (Supplementary ^{Table III} TABLE III Classification of names according to diagram in Fig. 3A a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field. )], and those who received a PhD in protozoology and established a group in another field [group e: 188 (Supplementary ^{Table III} TABLE III Classification of names according to diagram in Fig. 3A a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field. )]. Finally, we determined the percentage of people who left Brazilian protozoology to contribute to other fields of Brazilian science. To obtain this number, we divided the number of people classified as group e in Supplementary ^{Table III} TABLE III Classification of names according to diagram in Fig. 3A a: scientists working or who worked in the past in protozoology in Brazil; b: scientists working in protozoology outside of Brazil that were advisors of Brazilians; c: scientists that did not work in protozoology during their PhD or establish a research interest in this field but were advisors of scientists that migrated to protozoology; d: persons who developed their PhD in protozoology but are now involved in activities other than science; e: scientists who developed their PhD in protozoology but established research in another field. (188) by the total number who received a PhD in protozoology. This analysis demonstrated that protozoology provided 16.7% of its PhDs to other fields of science.

Academic genealogy of Brazilian protozoologists - Finally, we constructed an academic genealogy (Fig. 6) that included all names classified as protozoologists to reflect the scenario of protozoology in Brazil. The resulting structure is a forest containing one tree for each scientist who entered Brazilian protozoology. A detailed view of this academic genealogy is available from professor.ufabc.edu.br/~jesus.mena/brazilian-protozoology-scenario/. It is clear that protozoology expanded in the mid-1970s. It is also clear that protozoology today consists of the descendants of the pioneers as well as other scientists who migrated to protozoology and supervised their students in this field.

Fig. 6
: academic genealogy of Brazilian protozoology protozoologists (group a in Fig. 3) were included in this graph. Each circle represents one researcher and lines represent student-supervisor relationships. Persons identified as pioneers are shown in red, persons directly influenced by pioneers (students or students of their students) are shown in blue, and persons who arrived in protozoology after the pioneers and their descendants are shown in green. The x-axis shows the year of the conclusion of the PhD in protozoology or, for those who did not receive a PhD in protozoology, the year that they migrated to protozoology.

DISCUSSION

The analysis of the dynamics of Brazilian protozoology over the past century based on database searches from 1987-2011 allowed us to track and identify scientists who made important contributions by acting as the pioneers of this field. Moreover, we could determine the percentage of scientists immigrating to protozoology as well as the percentage of scientists who were supervised in protozoology but established a research group in another field. The field of Brazilian protozoology comprises at least 907 researchers. Certainly, there are other protozoologists who were not covered by our criteria and therefore were not included in our analysis. The interesting result is that a large number of people working in this field are the result of the efforts of 20 pioneers who introduced protozoa as biological models or drug targets in the period between 1909-1974. In a seminal paper published inMemórias do Instituto Oswaldo Cruz, Carlos Chagas describedT. cruzi and thereby introduced the study of protozoology in Brazil (Chagas 1909Chagas C 1909. Nova tripanozomiaze humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzin. gen., n. sp., ajente etiolojico de nova entidade morbida do homem.Mem Inst Oswaldo Cruz 1: 159-218.). Surprisingly, no descendants were identified for Carlos Chagas, probably because his descendants were clinical doctors and therefore were not classified as protozoologists according to the criteria used in this study. However, Carlos Chagas’s work at the beginning of the previous century was so complete in showing the causal agent of a disease and its relationship to an insect vector that it still inspires researchers today.

In the 1940s, Samuel Pessoa inaugurated his huge contribution to the field by studying the behaviour of Leishmania in tissues (Pessoa & Barreto 1945Pessoa SB, Barreto MP 1945. Sobre a localização dos parasitos nos tecidos e a intensidade do parasitismo na leishamaniase tegumentar americana.Rev Paul Med26: 355-357.) and the geographic distribution of phlebotomines (Barreto & Pessoa 1946)Barreto MP, Pessoa SB 1946. Contribuição para o estudo da distribuição geográfica dos flebótomos americanos (Diptera, Psychoidae).An Paul Med Cir51: 261.. Hertha Meyer published on T. cruzi cultivation (Meyer & de Oliveira 1948Meyer H, de Oliveira MX 1948. Cultivation of Trypanosoma cruzi in tissue cultures; a four day study.Parasitology39: 91-94.); this field of study evolved to include her contribution regarding the structural analysis of this organism. In the 1950s, the study of protozoa in Brazil expanded with Amilcar Viana Martins, Leonidas Deane, and Maria Deane, who investigated the epidemiology of leishmaniasis (Deane & Deane 1954Deane LM, Deane MP 1954. Dogs naturally infected byLeishamniadonovani in Ceará. Hospital45: 703-707., Martins et al. 1956)Martins AV, Brener Z, Mourão OG, Lima MM, de Souza MA, da Silva JE 1956. Autochthonous kala-azar in Minas Gerais. Rev Bras Malariol Doencas Trop8: 555-563., Zigman Brener and Washington Luiz Tafuri, who contributed to our understanding of Chagas disease (Brener 1952Brener Z 1952. Complement fixation with L. brasiliensis in cutaneous American leishmaniasis and in Chagas disease. Hospital41: 269-275., de Queiroz & Tafuri 1957)de Queiroz JM, Tafuri WL 1957. Lesion of the eye and adnexa in experimental schizotrypanosomiaisis in albino rats. Rev Assoc Med Bras3: 256-262., José Rodrigues da Silva, who investigated hepatic problems related to Leishmania and amoeba infections (da Silva & de Paola 1957da Silva JR, de Paola D 1957. Histochemical changes in the hepatic reticuloendothelial system in kala-azar. Med Cir Farm19: 211-215., daSilva & Torres 1957)da Silva JR, Torres E 1957. Amebic abscess of the liver; review and case report. Rev Bras Gastroenterol9: 215-234., and Wladimir Lobato Paraense, who was interested in Plasmodium (Paraense 1952)Paraense WL 1952. Observations on a Brazilian strain ofPlasmodium circumflexum. Mem Inst Oswaldo Cruz 50: 229-241.. Then, over the next two decades, a new group of scientists migrated into protozoology. Their studies included the detection and treatment of Trypanosoma,Leishmania, Toxoplasma, andPlasmodium by Raymundo Martins de Castro (Sampaio et al. 1971)Sampaio SA, Castro RM, Rivitti E, Sampaio SA 1971. Treatment of mucocutaneous (American) leishmaniasis with amphotericin B: report of 70 cases.Int J Dermatol12: 388-394., Aluízio Prata (Prata 1963Prata A 1963. Treatment of kala-azar with amphotericin B.Trans R Soc Trop Med Hyg57: 266-268.), Mario Camargo (Camargo 1964bCamargo ME 1964b. Improved technique of indirect immunofluorescence for serological diagnosis of toxoplasmosis. Rev Inst Med Trop Sao Paulo 6: 117-118.), and Thales de Brito (de Brito et al. 1962)de Brito T, Meira JA, Bassoi ON 1962. Contribution to the study of malaria. II. Pathology of the liver in acute malaria. Rev Inst Med Trop Sao Paulo 4: 105-111., the biology of trypanosomatids by Walter Colli (Alves & Colli 1974)Alves MJM, Colli W 1974. Agglutination of Trypanosoma cruzi by concavalin A. J Protozool21: 575-578., Erney Camargo (Camargo 1964aCamargo EP 1964a. Growth and differantiation in Trypanosoma cruzi. I. Origin of metacyclic trypanosomas in liquid media.Rev Inst Med Trop Sao Paulo6: 93-100.), and Isaac Roitman (Roitman 1969), and epidemiological approaches to studying diseases and hosts by Jeffrey Shaw (Shaw & Lainson 1968)Shaw J, Lainson R 1968. Leishmaniasis in Brazil. II. Observation on enzootic leishamaniasis in the lower Amazonian Basin. Trans R Soc Trop Med Hyg62: 396-405., Jayme Neves (Neves et al. 1961)Neves J, Mayrink W, Mourao OG, Cardoso JP 1961. Kala-azar in Minas Gerais. Clinical and immuno-serological survey in the Hospital das Clínicas and in the Santa Casa de Misericórdia de Belo Horizonte, to identify cases of kala-azar. Hospital59: 1165-1177., and Astolpho Ferraz de Siqueira (Barreto et al. 1963)Barreto MP, Siqueira AF, Correa FM 1963. Study on reservoirs and forest vectors of Trypanosoma cruzi. I. Presence ofTriatoma infestans (Hemiptera, Reduviidae) in forest outhouses. Rev Inst Med Trop Sao Paulo5: 289-293.. These studies concluded the first phase of Brazilian protozoology. The co-authors of the works cited above certainly contributed to Brazilian protozoology and could be identified as founders of Brazilian protozoology.

The pioneers/founders, together with the students they supervised, nucleated the Brazilian protozoologist network. Thus, the environment favouring the construction of this field in Brazilian science was created. By supervising new students, organising scientific meetings and working side by side with agencies to create programmes for financial support, these scientists solidified the foundations of Brazilian protozoology and allowed the influx of new scientists into this area.

Immigration occurred in two waves. The entry of scientists between 1978-1993 might be a consequence of the creation of the Integrated Program for Endemic Diseases (PIDE), which was the Funding Programme from the Brazilian Council for Science Development (CNPq) that operated between 1976-1986. This programme invested the equivalent of 12 million American dollars in groups working in approximately 200 projects in endemic diseases (Gonçalves et al. 1988Gonçalves A, Albuquerque RH, Lins MG, Neiva DS, Souza GF 1988. Avaliação exploratória de atuação bienal do Programa Integrado de Doenças Endêmicas do Conselho Nacional de Desenvolvimento Científico e Tecnológico PIDE/CNPq. Rev Inst Med Trop Sao Paulo30: 109-117.). Due to its differentiated financial policy, which means an initiative to influence the development of a special area, the programme had a huge impact on attracting more groups to work in protozoology, and our data reinforce this importance.

The second wave of incoming scientists occurred after 1998 and might be the consequence of the elevated number of fellowships and resources offered by the CNPq. In this sense, national politics favoured Brazilian science, and protozoology took advantage of this situation. However, we cannot forget the contribution of International Funding Programmes such as the Tropical Diseases Research (TDR) of the World Health Organization.

By tracking students who completed their PhD in protozoology, we observed that 85% of them were still involved with science. Considering that the other 15% might include people who teach in private universities using the knowledge acquired during their PhD, we can conclude that the resources invested in protozoology were very well returned to society. However, it is time to reflect on whether the current number of students completing their PhDs will be harnessed in Brazil as has occurred in the past.

The scenario of protozoology in Brazil, as shown in Fig. 6, presents an increasing trend. Although the immigration dynamics presented in Fig. 5 showed a possible decrease in interest, Brazilian protozoology is the result of the work of pioneers and also (as evidenced by the green dots in Fig. 6) the consequence of the immigration of many scientists to protozoology who supervised their students in this area. It is important to reinforce that this flux requires financial support or strong funding programmes such as the PIDE and TDR.

Our goal in this communication was to show the dynamics of protozoologists and the impact of protozoology on Brazilian science. The same approach can be used to study contributions in other fields. The use of different criteria can group people in various ways to reveal other trees and identify other pioneers, even in protozoology. The genealogy presented here is one of multiple possible methods to track our past and hopefully point to our future.

From Isaac Newton to Stephen Hawking, the idea of “having seen further by standing on the shoulders of giants” has been used in science to recognise past mentors for new discoveries. We expect that in addition to serving as a source for research on the historical and paradigmatic aspects of Brazilian protozoology and positioning the contributions of the field to Brazilian science, this paper may be seen as a form of acknowledgement of the pioneering researchers who built the foundations of our work and inspired new generations of protozoology.

Supplementary data

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TABLE I
Descriptors used to screen theses on Coordination for the Improvement of Higher Education Personnel database

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TABLE II
Scientists that supervised at least 10 theses/dissertations containing at least one of the 60 descriptors present on Supplementary Table I

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TABLE III
Classification of names according to diagram in Fig. 3A

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TABLE IV
Classification of names that developed (1) or not (2) PhD in protozoology

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TABLE V
Year that persons who did not develop PhD in protozoology published in this field

ACKNOWLEDGEMENTS

To Marcelo Reis, for grateful discussions concerning data analysis.

REFERENCES

Alves MJM, Colli W 1974. Agglutination of Trypanosoma cruzi by concavalin A. J Protozool21: 575-578.
Andersen JP, Hammarfelt B 2011. Price revisited: on the growth of dissertations in eight research fields. Scientometrics88: 371-383.
Barreto MP, Pessoa SB 1946. Contribuição para o estudo da distribuição geográfica dos flebótomos americanos (Diptera, Psychoidae).An Paul Med Cir51: 261.
Barreto MP, Siqueira AF, Correa FM 1963. Study on reservoirs and forest vectors of Trypanosoma cruzi I. Presence ofTriatoma infestans (Hemiptera, Reduviidae) in forest outhouses. Rev Inst Med Trop Sao Paulo5: 289-293.
Blackburn EH, Gall JG 1978. Tandemly repeated sequence at the termini of the extrachromosomal ribosomal RNA genes inTetrahymena J Mol Biol120: 33-53.
Brener Z 1952. Complement fixation with L. brasiliensis in cutaneous American leishmaniasis and in Chagas disease. Hospital41: 269-275.
Calkins GN 1911. The scope of protozoology.Science34: 129-138.
Camargo EP 1964a. Growth and differantiation in Trypanosoma cruzi I. Origin of metacyclic trypanosomas in liquid media.Rev Inst Med Trop Sao Paulo6: 93-100.
Camargo ME 1964b. Improved technique of indirect immunofluorescence for serological diagnosis of toxoplasmosis. Rev Inst Med Trop Sao Paulo 6: 117-118.
Chagas C 1909. Nova tripanozomiaze humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzin. gen., n. sp., ajente etiolojico de nova entidade morbida do homem.Mem Inst Oswaldo Cruz 1: 159-218.
Clayton CE 2002. Life without transcriptional control? From fly to man and back again. Embo J 21: 1881-1888.
Cordova KE, Furukawa H, Yaghi OM 2015. The development of global science. ACS Cent Sci1: 18-23.
da Silva JR, de Paola D 1957. Histochemical changes in the hepatic reticuloendothelial system in kala-azar. Med Cir Farm19: 211-215.
da Silva JR, Torres E 1957. Amebic abscess of the liver; review and case report. Rev Bras Gastroenterol9: 215-234.
de Brito T, Meira JA, Bassoi ON 1962. Contribution to the study of malaria. II. Pathology of the liver in acute malaria. Rev Inst Med Trop Sao Paulo 4: 105-111.
de Queiroz JM, Tafuri WL 1957. Lesion of the eye and adnexa in experimental schizotrypanosomiaisis in albino rats. Rev Assoc Med Bras3: 256-262.
Deane LM, Deane MP 1954. Dogs naturally infected byLeishamniadonovani in Ceará. Hospital45: 703-707.
Ferguson MA 1999. The structure, biosynthesis, and function of glycosylphosphatidylinositol anchors, and the contribution of trypanosome research. J Cell Sci112: 2799-2809.
Ferguson MA, Haldar K, Cross GA 1985. Trypanosoma brucei variant surface glycoprotein has a sn-1,2-dimyristyl glycerol membrane anchor at its COOH terminus. J Biol Chem260: 4963-4968.
Gonçalves A, Albuquerque RH, Lins MG, Neiva DS, Souza GF 1988. Avaliação exploratória de atuação bienal do Programa Integrado de Doenças Endêmicas do Conselho Nacional de Desenvolvimento Científico e Tecnológico PIDE/CNPq. Rev Inst Med Trop Sao Paulo30: 109-117.
Heinzel FP, Sadick MD, Holaday BJ, Coffman RL, Locksley RM 1989. Reciprocal expression of interferon gamma of interleukin 4 during the resolution or progression of murine leishmaniasis. Evidence for expansion of distinct helper T-cell subsets. J Exp Med169: 59-72.
Levenshtein VI 1966. Binary codes capable of correcting deletions, insertions, and reversals. Soviet Physics-Doklady10: 707-710.
Martins AV, Brener Z, Mourão OG, Lima MM, de Souza MA, da Silva JE 1956. Autochthonous kala-azar in Minas Gerais. Rev Bras Malariol Doencas Trop8: 555-563.
Mayer MG, Floeter-Winter LM 2012. Identification of SL additiontrans-splicing acceptor sites in the internal trasncribed spacer I region of pre-rRNA in Leishmania (Leishmania) amazonensis Mem Inst Oswaldo Cruz107: 1070-1072.
Mena-Chalco JP, Rocha V 2014. Caracterização do banco de teses e dissertações da CAPES. In 4º Encontro Brasileiro de Bibliometria e Cientometria, 14-16 de maio de 2014, Recife, 11 pp.
Meyer H, de Oliveira MX 1948. Cultivation of Trypanosoma cruzi in tissue cultures; a four day study.Parasitology39: 91-94.
Moraes LCA, França EL, Pessoa RS, Fagundes DLG, Hernandes MG, Ribeiro VP, Gomes MA, Honório-França C 2015. The effect of INF-g and TGF-b in the functional activity of mononuclear cells in the presence ofEntamoeba histolytica Parasit Vectors8: 413.
Neves J, Mayrink W, Mourao OG, Cardoso JP 1961. Kala-azar in Minas Gerais. Clinical and immuno-serological survey in the Hospital das Clínicas and in the Santa Casa de Misericórdia de Belo Horizonte, to identify cases of kala-azar. Hospital59: 1165-1177.
Paraense WL 1952. Observations on a Brazilian strain ofPlasmodium circumflexum Mem Inst Oswaldo Cruz 50: 229-241.
Pessoa SB, Barreto MP 1945. Sobre a localização dos parasitos nos tecidos e a intensidade do parasitismo na leishamaniase tegumentar americana.Rev Paul Med26: 355-357.
Prata A 1963. Treatment of kala-azar with amphotericin B.Trans R Soc Trop Med Hyg57: 266-268.
Roitman I 1969. Experiments in growing Trypanosoma conorhini on a synthetic medium. J Protozoology16: 36.
Sampaio SA, Castro RM, Rivitti E, Sampaio SA 1971. Treatment of mucocutaneous (American) leishmaniasis with amphotericin B: report of 70 cases.Int J Dermatol12: 388-394.
Shaw J, Lainson R 1968. Leishmaniasis in Brazil. II. Observation on enzootic leishamaniasis in the lower Amazonian Basin. Trans R Soc Trop Med Hyg62: 396-405.
Simpson AG, Stevens JR, Lukes J 2006. The evolution and diversity of kinetoplastid flagellates. Trends Parasitol 22: 168-174.
Sugimoto CR 2014. Academic genealogy. In B Cronin, CR Sugimoto (eds.), Beyond bibliometrics: harnessing multidimensional indicators of scholarly impact, MIT Press, Cambridge, p. 365-382.

Financial support: FAPESP (2013/07467-1 to MCE), CNPq (461757/2014-1 to JPM-C) MCE and LMF-W are research fellows from CNPq (306376/2012-1 and 307587/2014-2 respectively).

Publication Dates

Publication in this collection
Jan 2016

History

Received
8 Oct 2015
Accepted
8 Dec 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Alves MJM, Colli W 1974. Agglutination of Trypanosoma cruzi by concavalin A. J Protozool21: 575-578.

[2] Andersen JP, Hammarfelt B 2011. Price revisited: on the growth of dissertations in eight research fields. Scientometrics88: 371-383.

[3] Barreto MP, Pessoa SB 1946. Contribuição para o estudo da distribuição geográfica dos flebótomos americanos (Diptera, Psychoidae).An Paul Med Cir51: 261.

[4] Barreto MP, Siqueira AF, Correa FM 1963. Study on reservoirs and forest vectors of Trypanosoma cruzi I. Presence ofTriatoma infestans (Hemiptera, Reduviidae) in forest outhouses. Rev Inst Med Trop Sao Paulo5: 289-293.

[5] Blackburn EH, Gall JG 1978. Tandemly repeated sequence at the termini of the extrachromosomal ribosomal RNA genes inTetrahymena J Mol Biol120: 33-53.

[6] Brener Z 1952. Complement fixation with L. brasiliensis in cutaneous American leishmaniasis and in Chagas disease. Hospital41: 269-275.

[7] Calkins GN 1911. The scope of protozoology.Science34: 129-138.

[8] Camargo EP 1964a. Growth and differantiation in Trypanosoma cruzi I. Origin of metacyclic trypanosomas in liquid media.Rev Inst Med Trop Sao Paulo6: 93-100.

[9] Camargo ME 1964b. Improved technique of indirect immunofluorescence for serological diagnosis of toxoplasmosis. Rev Inst Med Trop Sao Paulo 6: 117-118.

[10] Chagas C 1909. Nova tripanozomiaze humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzin. gen., n. sp., ajente etiolojico de nova entidade morbida do homem.Mem Inst Oswaldo Cruz 1: 159-218.

[11] Clayton CE 2002. Life without transcriptional control? From fly to man and back again. Embo J 21: 1881-1888.

[12] Cordova KE, Furukawa H, Yaghi OM 2015. The development of global science. ACS Cent Sci1: 18-23.

[13] da Silva JR, de Paola D 1957. Histochemical changes in the hepatic reticuloendothelial system in kala-azar. Med Cir Farm19: 211-215.

[14] da Silva JR, Torres E 1957. Amebic abscess of the liver; review and case report. Rev Bras Gastroenterol9: 215-234.

[15] de Brito T, Meira JA, Bassoi ON 1962. Contribution to the study of malaria. II. Pathology of the liver in acute malaria. Rev Inst Med Trop Sao Paulo 4: 105-111.

[16] de Queiroz JM, Tafuri WL 1957. Lesion of the eye and adnexa in experimental schizotrypanosomiaisis in albino rats. Rev Assoc Med Bras3: 256-262.

[17] Deane LM, Deane MP 1954. Dogs naturally infected byLeishamniadonovani in Ceará. Hospital45: 703-707.

[18] Ferguson MA 1999. The structure, biosynthesis, and function of glycosylphosphatidylinositol anchors, and the contribution of trypanosome research. J Cell Sci112: 2799-2809.

[19] Ferguson MA, Haldar K, Cross GA 1985. Trypanosoma brucei variant surface glycoprotein has a sn-1,2-dimyristyl glycerol membrane anchor at its COOH terminus. J Biol Chem260: 4963-4968.

[20] Gonçalves A, Albuquerque RH, Lins MG, Neiva DS, Souza GF 1988. Avaliação exploratória de atuação bienal do Programa Integrado de Doenças Endêmicas do Conselho Nacional de Desenvolvimento Científico e Tecnológico PIDE/CNPq. Rev Inst Med Trop Sao Paulo30: 109-117.

[21] Heinzel FP, Sadick MD, Holaday BJ, Coffman RL, Locksley RM 1989. Reciprocal expression of interferon gamma of interleukin 4 during the resolution or progression of murine leishmaniasis. Evidence for expansion of distinct helper T-cell subsets. J Exp Med169: 59-72.

[22] Levenshtein VI 1966. Binary codes capable of correcting deletions, insertions, and reversals. Soviet Physics-Doklady10: 707-710.

[23] Martins AV, Brener Z, Mourão OG, Lima MM, de Souza MA, da Silva JE 1956. Autochthonous kala-azar in Minas Gerais. Rev Bras Malariol Doencas Trop8: 555-563.

[24] Mayer MG, Floeter-Winter LM 2012. Identification of SL additiontrans-splicing acceptor sites in the internal trasncribed spacer I region of pre-rRNA in Leishmania (Leishmania) amazonensis Mem Inst Oswaldo Cruz107: 1070-1072.

[25] Mena-Chalco JP, Rocha V 2014. Caracterização do banco de teses e dissertações da CAPES. In 4º Encontro Brasileiro de Bibliometria e Cientometria, 14-16 de maio de 2014, Recife, 11 pp.

[26] Meyer H, de Oliveira MX 1948. Cultivation of Trypanosoma cruzi in tissue cultures; a four day study.Parasitology39: 91-94.

[27] Moraes LCA, França EL, Pessoa RS, Fagundes DLG, Hernandes MG, Ribeiro VP, Gomes MA, Honório-França C 2015. The effect of INF-g and TGF-b in the functional activity of mononuclear cells in the presence ofEntamoeba histolytica Parasit Vectors8: 413.

[28] Neves J, Mayrink W, Mourao OG, Cardoso JP 1961. Kala-azar in Minas Gerais. Clinical and immuno-serological survey in the Hospital das Clínicas and in the Santa Casa de Misericórdia de Belo Horizonte, to identify cases of kala-azar. Hospital59: 1165-1177.

[29] Paraense WL 1952. Observations on a Brazilian strain ofPlasmodium circumflexum Mem Inst Oswaldo Cruz 50: 229-241.

[30] Pessoa SB, Barreto MP 1945. Sobre a localização dos parasitos nos tecidos e a intensidade do parasitismo na leishamaniase tegumentar americana.Rev Paul Med26: 355-357.

[31] Prata A 1963. Treatment of kala-azar with amphotericin B.Trans R Soc Trop Med Hyg57: 266-268.

[32] Roitman I 1969. Experiments in growing Trypanosoma conorhini on a synthetic medium. J Protozoology16: 36.

[33] Sampaio SA, Castro RM, Rivitti E, Sampaio SA 1971. Treatment of mucocutaneous (American) leishmaniasis with amphotericin B: report of 70 cases.Int J Dermatol12: 388-394.

[34] Shaw J, Lainson R 1968. Leishmaniasis in Brazil. II. Observation on enzootic leishamaniasis in the lower Amazonian Basin. Trans R Soc Trop Med Hyg62: 396-405.

[35] Simpson AG, Stevens JR, Lukes J 2006. The evolution and diversity of kinetoplastid flagellates. Trends Parasitol 22: 168-174.

[36] Sugimoto CR 2014. Academic genealogy. In B Cronin, CR Sugimoto (eds.), Beyond bibliometrics: harnessing multidimensional indicators of scholarly impact, MIT Press, Cambridge, p. 365-382.