Serum proteinogram of the Campeiro horse

Souza, A.F.; Schade, J.; Ramos, A.F.; Albuquerque, M.S.M.; Fonteque, G.V.; Costa, D.; Muller, T.R.; Fonteque, J.H.

doi:10.1590/1678-4162-10102

ABSTRACT

The aim of this study to measure the fractions of the total serum proteins of the Campeiro horse and identify the influences of biological variants. Blood samples were taken in 138 horses of the breed Campeiro for measuring the concentration of total serum protein by the biuret method. Serum concentrations of protein fractions were measured by electrophoresis using agarose gel. Groups were formed according to age, sex and reproductive condition. The average values of serum fractions: albumin (2.85±0.36g/dl), alpha 1 (0.28±0.11g/dl), alpha 2 (0.26±0.08g/dL) beta 1 (0.57±0.15g/dl), beta 2 (0.89±0.28g/dL), gamaglobulinas (1.86±0.34g/dL), albumin/globulin ratio (0.75±0.18) and 2.5% percentile and 97.5% had slight differences in relation to the reference interval proposed for the species. They observed higher values of alpha 1 and 2 globulins in the group from that had six to eight years old and gammaglobulins in group above 13 years old. Serum protein concentrations were similar in horses and mares and between non-pregnant and pregnant. Sex and pregnancy status did not affect serum proteinogram. Alpha and gammaglobulins have higher values as the age increases. Serum proteinogram of Campeiro horses shows variations that have to be considered in the interpretation of laboratory tests.

Keywords:
albumin; clinical patology; globulins; serum proteins

RESUMO

Este trabalho tem por objetivo mensurar as frações das proteínas totais séricas de equinos Campeiros e identificar as influências de variantes biológicas. Foram colhidas amostras de sangue de 138 equinos, machos e fêmeas da raça Campeiro. A determinação da concentração de proteínas totais séricas foi realizada pelo método de biureto. As concentrações séricas das frações proteicas foram determinadas por eletroforese, utilizando-se gel de agarose. Formaram-se grupos em relação à idade, ao sexo e à condição reprodutiva. Os valores médios das frações séricas albumina (2,85±0,36g/dL), alfa 1 (0,28±0,11g/dL), alfa 2 (0,26±0,08g/dL), beta 1 (0,57±0,15g/dL), beta 2 (0,89±0,28g/dL), gamaglobulinas (1,86±0,34g/dL), relação albumina/globulina (0,75±0,18) e os percentis 2,5% e 97,5% apresentaram diferenças pontuais em relação aos intervalos propostos para a espécie. Observaram-se maiores valores de alfa 1, alfa 2 globulinas, no grupo de seis a oito anos, e de gamaglobulinas, no grupo acima de 13 anos de idade. O proteinograma sérico foi similar entre machos e fêmeas e entre fêmeas vazias e gestantes. Sexo e estado gestacional não afetaram o proteinograma sérico. Alfa e gamaglobulinas têm incrementos em função de idades crescentes. O proteinograma sérico de equinos Campeiros tem variações que devem ser consideradas em exames laboratoriais.

Palavras-chave:
albumina; patologia clínica; globulinas; proteínas séricas

INTRODUCTION

Electrophoresis of serum proteins is a useful diagnostic tool in veterinary medicine, which can provide important information and facilitate the clinical differentiation of diproteinemias (Keren et al., 1999KEREN, D.F.; ALEXANIAN, R.; GOEKEN, J.A. et al. Guidelines for clinical and laboratory evaluation of patients with monoclonal gammopathies. Arch. Pathol. Lab. Med., v.123, p.106-107, 1999.). Various changes in the fractions of serum proteins can occur and these can be indicative of non-specific disease processes or markers in some potential pathological conditions.

The standard physiological electrophoretic determination in different species is useful in differentiation of healthy from unhealthy individuals in which routine tests are not effective for clinical decision making by providing a basis of direction for the choice of laboratory tests more specified (Eckersall, 2008ECKERSALL, P.D. Proteins, proteomics, and the dysproteinemias. In: KANEKO, J.J.; HARVEY, J.W.; BRUSS, M.L. (Eds.). Clinical biochemistry of domestic animals. 6.ed. Boston: Elsevier Academic Press, 2008. p.117-156.; Mallard et al., 1998MALLARD, B.A.; DEKKERS, J.C.; IRELAND, M.J. et al. Alteration in immune responsiveness during the peripartum period and its ramification on dairy cow and calf health. J. Dairy Sci., v.81, p.585-595, 1998.).

The fractionation of serum proteins is a useful test in the equine medical clinic routine, but is not yet sufficiently standardized (Riond et al., 2009RIOND, B.; WENGER‐RIGGENBACH, B.; HOFMANN‐LEHMANN, R.; LUTZ, H. Serum protein concentrations from clinically healthy horses determined by agarose gel electrophoresis. Vet. Clin. Pathol., v.38, p.73-77, 2009.), in which analogous values of reference that do not fit relevant characteristics to the animal or breed may result in erroneous interpretations.

The Campeiro horse is locally adapted in the Planalto Serrano Catarinense region (southern Brazil) and has a characteristic gaited to be credited to exist organic adaptations to the environment, as they were observed in other studies (Fonteque et al., 2016FONTEQUE, J.H.; CECCATTO, M.L.; BAGIO, R.M. et al. Hematological profile, total plasma protein and fibrinogen concentrations of clinically healthy adult Campeiro horses. Ciênc. Rural, v.46, p.144-149, 2016.; Souza et al., 2016SOUZA, A.F.; SCHADE, J.; KUNZ, J.R. et al. Perfil bioquímico sérico de equinos clinicamente sadios da raça Campeiro. Arq. Bras. Med. Vet. Zootec., v.68, p.839-844, 2016.). Therefore, knowledge of protein fractions that make up the serum protein profile, its proportions and the influence of biological factors associated in sex, age, reproductive period (Miller et al., 1998MILLER, I.; HAYNES, P.; GEMEINER, M. et al. Proteins of rat serum: II. Influence of some biological parameters of the two‐dimensional electrophoresis pattern. Electrophoresis, v.19, p.1493-1500, 1998.), are necessary for knowledge of the physiologic standards of the race and its variations. Thus there will be more accuracy in the interpretation of laboratory tests used to aid diagnosis of diseases.

This study aims to measure the serum protein profile through the fractionation of albumin, alpha 1, alpha 2, beta 1, beta 2 and gammaglobulins and the influence of biological variables: age, sex and pregnancy, in adult horses of the Campeiro breed.

MATERIALS AND METHOD

The study was approved of the Santa Catarina State University Animal Ethics Committee (n° 01.05.14). Animal owners gave consent for their inclusion in the study.

Were used 138 horses with a mean age 9.8±5.6 years, being that 14 males (10.15%) and 124 females (88, 85%) registered of the Campeiro breed, from conservation properties in the city of Lages, Curitibanos, Campos Novos and Concordia in the Santa Catarina State and in the city of Caxias do Sul, in the State of Rio Grande do Sul, located in southern Brazil.

Blood samples were collected by venipuncture of the external jugular in vacuum tubes of 10mL without anticoagulant. After centrifugation, serum was frozen at -20°C and stored in tubes (Eppendorf, Hamburg, Germany) until laboratory analyzes. Measurements of the concentration of total serum protein (TSP) was performed by the biuret method using commercially available reagents. Serum concentrations of protein fractions of albumin, alpha 1, alpha 2, beta 1, beta 2 and gamma globulin were performed by electrophoresis by using the agarose gel method (Celmgel, CELM general agarose gel), Tris buffer pH 9.5 (CELM), and electrophoretic run for 20min in 100V current (System SE-250, CELM). After the procedure, the gel was stained with amido-black 2% and bleached with acetic acid 5%. The proportion of each protein fraction was established by the program software SDS-60 (CELM) of the SE-250 system (CELM) after scanner reading.

To evaluate the influence of factors related to age, sex and pregnancy on the variables studied are, the animals were divided into four groups according to age: three to five years; six to eight years; nine to 12 years and above 13 years, between males and females and also between pregnant and non-pregnant females.

The Shapiro-Wilk test was used to evaluate the normality of the data. Outliers were identified according to the Grubbs test. The reference intervals were calculated using percentiles 2.5%, 50% and 97.5%, supported on the recommendations of guidelines of Clinical Laboratory and Standards Institute (Defining…, 2008) and Geffré et al. (2009GEFFRÉ, A.; FRIEDRICHS, K.; HARR, K. et al. Reference values: a review. Vet. Clin. Pathol., v.38, p.288-298, 2009.). The coefficients of variation were calculated dividing the standard deviations by their respective means, and the expression as a percentage. It used the Kruskal-Wallis test followed Bonferroni test for multiple comparisons of means to the TSP and its fractions in different age groups. The comparison of males and females and between pregnant and non-pregnant females was performed with the Wilcoxon-Mann-Whitney test. Values of P <0.05 were considered significant.

RESULTS

Table 1 shows the mean values, standard deviation, relative values, and variation coeficient and percentiles of 2.5%, 50 and 97%. 5% of the concentration of TSP and its different fractions. One outlier was excluded from the gammaglobulin and two were excluded from the alpha 2 globulins.

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Table 1
Mean values, standard deviations (m±sd), relative values (RV), coefficient of variation (CV) and percentiles (2.5%, 50% and 97.5%) of total serum protein (TSP) and albumin (alb), alpha 1, alpha 2, beta 1, beta 2 and gamma globulins, and the albumin: globulin (A/G) ratio of 138 healthy adults of Campeiro horses

In relation to age, there were an increase (P <0.05) in alpha 1 and alpha 2 globulins in the group of six to eight years for the group of three to five years, remains similar in the following groups (Table 2). The gammaglobulin showed markedly increased values in the group of six to eight years, reaching the highest values in the group of animals with 13 years old or older (P <0.05) (Table 2).

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Table 2
Average values and standard deviations of total serum proteins (TSP) and protein fractions: albumin (alb), alpha 1, alpha 2, beta 1, beta 2 and gamma globulins and albumin: globulin (A/G) ratio in different age groups in 138 clinically healthy adult of Campeiro horses

The values are of serum protein fractions were similar between males and females and nonpregnant and pregnant mares (P <0.05) (Table 3).

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Table 3
Mean values and standard deviations of total serum proteins (TSP) and protein fractions: albumin (alb), alpha 1, alpha 2, beta 1, beta 2 and gamma globulins and albumin: globulin (A/G) ratio in relation to sex and at the time of gestation in healthy adult of Campeiro horses

DISCUSSION

Mean values and percentiles 2.5% and 97.5% were similar to those proposed reference intervals in Kaneko (1997KANEKO, J.J. Serum proteins and the dysproteinemias. In: _____. (Ed.). Clinical biochemistry of domestic animals. 5.ed. London: Academic Press, 1997. p.117-138.), except for the lower limits of albumin and alpha 2 globulins that were lower and upper limits of beta 2 and gamma globulins that were higher than those presented above as reference. Comparing the mean values and reference intervals proposed by Riond et al. (2009RIOND, B.; WENGER‐RIGGENBACH, B.; HOFMANN‐LEHMANN, R.; LUTZ, H. Serum protein concentrations from clinically healthy horses determined by agarose gel electrophoresis. Vet. Clin. Pathol., v.38, p.73-77, 2009.), higher values of beta 2 and gamma globulins and lower values of alpha 2 globulins and albumin/globulin (A/G) were observed, being similar to the others variables for horses of Campeiro breed. The relative values of alpha 1, beta 2 and gamma globulins shared the same differences of their concentrations, compared to results of Riond et al. (2009). Numeric distances of the differences of the results of this study in relation to the data of the above mentioned literature were small but sufficient to show different organic responses in the Campeiro breed compared to other racial groups, which may be related both to the environment as intrinsic factors.

The coefficients of variation were relatively high for fractions in alpha and beta globulins, with values close to 30%, demonstrating that modulation of these globulins may be related to the heterogeneity of the environment and/or genetic diversity of animals. Interpretation of the results of this test should be the light of benchmarks possible specific (Faria Filho et al., 2016). However, specific coefficients of variation information were not found in laboratory tests for better inference.

Age presented effect on protein profile, increases in alpha 1 and alpha 2 globulins were identified in group that had six to eight years in relation to the group of three to five years, and remains similar in the following groups. Showing the improvement of the immune system of the Campeiro horses as immunogenic insults occur over time. Similar results were found by Alberghina et al. (2010ALBERGHINA, D.; CASELLA, S.; VAZZANA, I. et al. Analysis of serum proteins in clinically healthy goats (Capra hircus) using agarose gel electrophoresis. Vet. Clin. Pathol., v.39, p.317-321, 2010.) when evaluating the proteinogram of healthy goats in which the group of animals of 5-12 years old presented higher concentrations of total protein and α-globulin than the group of 2-4 years of age, also by França et al. (2011FRANÇA, R.T.; COSTA, M.M.; MARTINS, D.B. et al. Protein profile of buffaloes of different ages. Acta Sci. Vet., v.39, p.995-999, 2011.) in which they identified an increase in total serum protein and gammaglobulin levels in buffaloes at 24 months compared to those at six months of age and by Alberghina et al. (2011), who observed an increase of alpha and betaglobulins from six years in dairy cows. The alpha fraction proteins, in most species except ruminants, are the most rapidly migrating globulins in electrophoresis. The alpha 1 antitrypsin protein corresponds to 90% of the normal alpha 1 zone peak and the alpha 2 zone is composed for several proteins such as haptoglobin, alpha-2 macroglobulin and ceruloplasmin, and all the alpha fraction classified as acute phase proteins (Eckersall, 2008ECKERSALL, P.D. Proteins, proteomics, and the dysproteinemias. In: KANEKO, J.J.; HARVEY, J.W.; BRUSS, M.L. (Eds.). Clinical biochemistry of domestic animals. 6.ed. Boston: Elsevier Academic Press, 2008. p.117-156.). The main function of this group of proteins it is to defend the body against pathological damage, helps restore homeostasis and regulates the different inflammation (Petersen et al., 2004PETERSEN, H.H.; NIELSEN, J.P.; HEEGAARD, P.M.H. Application of acute phase protein measurements in veterinary clinical chemistry. Vet. Res., v.35, p.163-187, 2004.). In addition to inflammatory conditions, these proteins can be released under normal physiological conditions (Kustritz, 2005KUSTRITZ, M.V.R. Pregnancy diagnosis and abnormalities of pregnancy dog. Theriogenology, v.64, p.755-765, 2005.).

The approximately 35% increase in the concentration of gammaglobulin in the group of older animals compared to the group of six to eight years, demonstrates the immune competence in older individuals due to exposure of a higher number of antigens. The gammaglobulin fraction is predominantly composed of immunoglobulins of various classes (IgG, IgA, IgM, IgD and IgE), with marked fluctuations concentrations observed during the first weeks of life in dependent mammals of passive transfer process (Schade et al., 2016SCHADE, J.; ROSSI, R.M.; FONTEQUE, G.V. et al. Transfer of passive immunity and serum proteinogram in calves of the Criollo Lageano hornless variety and Aberdeen Angus (Red Angus) breed in their first six months of life. Pesqui. Vet. Bras., v.36, p.33-40, 2016.; Perkins and Wagner, 2015PERKINS, G.A.; WAGNER, B. The development of equine immunity: Current knowledge on immunology in the young horse. Equine Vet. J., v.47, p.267-274, 2015.; LeBlanc et al., 1992). As the animal grows, the immune system acquires autonomy to produce its own antibodies, from the adaptive immune system cells and activated B cells in response to exposure to antigen (Jackson and Elsawa, 2015JACKSON, D.A.; ELSAWA, S.F. Factors regulating immunoglobulin production by normal and disease-associated plasma cells. Biomolecules, v.5, p.20-40, 2015.).

All males used in this study were stallions due to the fact that only intact males receive the definitive registration, according to the guidelines of the Brazilian Association of Campeiro Horse Breeders (ABRACCC). The greatest anabolic effects of testosterone to estrogen ratio (Eckersall, 2008ECKERSALL, P.D. Proteins, proteomics, and the dysproteinemias. In: KANEKO, J.J.; HARVEY, J.W.; BRUSS, M.L. (Eds.). Clinical biochemistry of domestic animals. 6.ed. Boston: Elsevier Academic Press, 2008. p.117-156.), seems not to influence the different protein fractions in Campeiro horses. Similar results were obtained by Cavalcante et al. (2012CAVALCANTE, P.H.; SILVA, A.C.C.; SAKAMOTO, S.M.; BLANCO, B.S. Serum proteins fractions in Brazilian-breed donkeys using Agarose gel electrophoresis. Turk. J. Vet. Anim. Sci., v.36, p.9-12, 2012.) when studying horses and donkeys. However, a research including castrated animals can be valid for more precise interpretation of fractions of serum proteins.

The pregnant females in this study were grouped regardless of the gestational period in which the data from the first two thirds of pregnancy that is expected to have little physiological impact (Ousey, 2004OUSEY, J.C. Peripartal endocrinology in the mare and foetus. Reprod. Domest. Anim., v.39, p.222-231, 2004.), seem to have been enough to not reflect in significant differences. Similar results were obtained in Lusitanian mares in the last third of pregnancy compared to postpartum (Agrícola et al., 2008AGRÍCOLA, R.; CARVALHO, H.; BARBOSA, M. et al. Blood lymphocyte subpopulations, neutrophil phagocytosis and proteinogram during late pregnancy and postpartum in mares. Reprod. Domest. Anim., v.43, p.212-217, 2008.). However, in another study elevations in concentrations of alpha 1, alpha 2 and gamma globulins during the two weeks before labor were identified (Bazzano et al., 2016BAZZANO, M.; GIUDICE, E.; FAZIO, F. et al. Serum protein electrophoresis profile during late pregnancy and early post partum period in mares. Anim. Sci. Pap. Rep., v.34, p.53-60, 2016.). In some species, the concentration of total protein decreases in maternal blood during pregnancy due to the reduction in the albumin, although there is a slight increase in globulin. In bitches, acute phase reaction occurs 21 days after fertilization, an increase of acute phase proteins and C-reactive protein in maternal serum (Vannucchi et al., 2002VANNUCCHI, C.I.; MIRANDOLA, R.M.; OLIVEIRA, C.M. Acute-phase protein profile during gestation and diestrous: proposal for an early pregnancy test in bitches. Anim. Reprod. Sci., v.74, p.87-99, 2002.; Eckersall et al., 1992ECKERSALL, P.D.; HARVEY, M.J.; FERGUSON, J. et al. Acute phase proteins in canine pregnancy (Canis familiaris). J. Reprod. Fert., v.47, p.159-164, 1992.). Grunberg et al. (2011GRUNBERG, W.; DONKIN, S.S.; CONSTABLE, P.D. Periparturient effects of feeding a low dietary cation-anion difference diet on acid-base, calcium, and phosphorus homeostasis and on intravenous glucose tolerance test in high producing dairy cows. J. Dairy Sci., v.94, p.727-745, 2011.) found lower concentrations of alpha-globulins in pre-partum cows in relation to cows in lactation and in anestrus, it this may be associated with immunoglobulins transfer from the bloodstream to the mammary gland colostrum for its synthesis.

CONCLUSION

The serum proteinogram of Campeiro horses presented specific variations that should be considered in laboratory tests. The alphas and gamma globulins show higher values according to the increase of age. Sex and gestational status did not affect serum proteinogram. The mean values and the proposed ranges can be used in the interpretation of equine serum protein concentrations as a reference for the Campeiro breed and as in comparative studies.

REFERENCES

AGRÍCOLA, R.; CARVALHO, H.; BARBOSA, M. et al. Blood lymphocyte subpopulations, neutrophil phagocytosis and proteinogram during late pregnancy and postpartum in mares. Reprod. Domest. Anim., v.43, p.212-217, 2008.
ALBERGHINA, D.; CASELLA, S.; VAZZANA, I. et al. Analysis of serum proteins in clinically healthy goats (Capra hircus) using agarose gel electrophoresis. Vet. Clin. Pathol., v.39, p.317-321, 2010.
ALBERGHINA, D.; GIANNETTO, C.; VAZZANA, I. et al. Reference intervals for total protein concentration, serum protein fractions, and albumin/globulin ratios in clinically healthy dairy cows. J. Vet. Diagn. Invest., v.23, p.111-114, 2011.
BAZZANO, M.; GIUDICE, E.; FAZIO, F. et al. Serum protein electrophoresis profile during late pregnancy and early post partum period in mares. Anim. Sci. Pap. Rep., v.34, p.53-60, 2016.
CAVALCANTE, P.H.; SILVA, A.C.C.; SAKAMOTO, S.M.; BLANCO, B.S. Serum proteins fractions in Brazilian-breed donkeys using Agarose gel electrophoresis. Turk. J. Vet. Anim. Sci., v.36, p.9-12, 2012.
DEFINING, establishing, and verifying reference intervals in the clinical laboratory. Approved guideline. 3.ed. Wayne, PA: CLSI, 2008.
ECKERSALL, P.D. Proteins, proteomics, and the dysproteinemias. In: KANEKO, J.J.; HARVEY, J.W.; BRUSS, M.L. (Eds.). Clinical biochemistry of domestic animals. 6.ed. Boston: Elsevier Academic Press, 2008. p.117-156.
ECKERSALL, P.D.; HARVEY, M.J.; FERGUSON, J. et al. Acute phase proteins in canine pregnancy (Canis familiaris). J. Reprod. Fert., v.47, p.159-164, 1992.
FARIA FILHO, D.E.; JARUCHE, Y.G.; LEAL, D.H.V. Classificação de coeficientes de variação na experimentação com coelhos no Brasil. Cienc. Anim. Bras., v.17, p.519-526, 2016.
FONTEQUE, J.H.; CECCATTO, M.L.; BAGIO, R.M. et al. Hematological profile, total plasma protein and fibrinogen concentrations of clinically healthy adult Campeiro horses. Ciênc. Rural, v.46, p.144-149, 2016.
FRANÇA, R.T.; COSTA, M.M.; MARTINS, D.B. et al. Protein profile of buffaloes of different ages. Acta Sci. Vet., v.39, p.995-999, 2011.
GEFFRÉ, A.; FRIEDRICHS, K.; HARR, K. et al. Reference values: a review. Vet. Clin. Pathol., v.38, p.288-298, 2009.
GRUNBERG, W.; DONKIN, S.S.; CONSTABLE, P.D. Periparturient effects of feeding a low dietary cation-anion difference diet on acid-base, calcium, and phosphorus homeostasis and on intravenous glucose tolerance test in high producing dairy cows. J. Dairy Sci., v.94, p.727-745, 2011.
JACKSON, D.A.; ELSAWA, S.F. Factors regulating immunoglobulin production by normal and disease-associated plasma cells. Biomolecules, v.5, p.20-40, 2015.
KANEKO, J.J. Serum proteins and the dysproteinemias. In: _____. (Ed.). Clinical biochemistry of domestic animals. 5.ed. London: Academic Press, 1997. p.117-138.
KEREN, D.F.; ALEXANIAN, R.; GOEKEN, J.A. et al. Guidelines for clinical and laboratory evaluation of patients with monoclonal gammopathies. Arch. Pathol. Lab. Med., v.123, p.106-107, 1999.
KUSTRITZ, M.V.R. Pregnancy diagnosis and abnormalities of pregnancy dog. Theriogenology, v.64, p.755-765, 2005.
LEBLANC, M.M.; TRAN, T.; BALDWIN, J.L.; PRITCHARD, E.L. Factors that influence passive transfer of immunoglobulins in foals. J. Am. Vet. Med. Assoc., v.200, p.179-183, 1992.
MALLARD, B.A.; DEKKERS, J.C.; IRELAND, M.J. et al. Alteration in immune responsiveness during the peripartum period and its ramification on dairy cow and calf health. J. Dairy Sci., v.81, p.585-595, 1998.
MILLER, I.; HAYNES, P.; GEMEINER, M. et al. Proteins of rat serum: II. Influence of some biological parameters of the two‐dimensional electrophoresis pattern. Electrophoresis, v.19, p.1493-1500, 1998.
OUSEY, J.C. Peripartal endocrinology in the mare and foetus. Reprod. Domest. Anim., v.39, p.222-231, 2004.
PERKINS, G.A.; WAGNER, B. The development of equine immunity: Current knowledge on immunology in the young horse. Equine Vet. J., v.47, p.267-274, 2015.
PETERSEN, H.H.; NIELSEN, J.P.; HEEGAARD, P.M.H. Application of acute phase protein measurements in veterinary clinical chemistry. Vet. Res., v.35, p.163-187, 2004.
RIOND, B.; WENGER‐RIGGENBACH, B.; HOFMANN‐LEHMANN, R.; LUTZ, H. Serum protein concentrations from clinically healthy horses determined by agarose gel electrophoresis. Vet. Clin. Pathol., v.38, p.73-77, 2009.
SCHADE, J.; ROSSI, R.M.; FONTEQUE, G.V. et al. Transfer of passive immunity and serum proteinogram in calves of the Criollo Lageano hornless variety and Aberdeen Angus (Red Angus) breed in their first six months of life. Pesqui. Vet. Bras., v.36, p.33-40, 2016.
SOUZA, A.F.; SCHADE, J.; KUNZ, J.R. et al. Perfil bioquímico sérico de equinos clinicamente sadios da raça Campeiro. Arq. Bras. Med. Vet. Zootec., v.68, p.839-844, 2016.
VANNUCCHI, C.I.; MIRANDOLA, R.M.; OLIVEIRA, C.M. Acute-phase protein profile during gestation and diestrous: proposal for an early pregnancy test in bitches. Anim. Reprod. Sci., v.74, p.87-99, 2002.

Publication Dates

Publication in this collection
06 June 2019
Date of issue
Mar-Apr 2019

History

Received
05 June 2017
Accepted
02 July 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AGRÍCOLA, R.; CARVALHO, H.; BARBOSA, M. et al. Blood lymphocyte subpopulations, neutrophil phagocytosis and proteinogram during late pregnancy and postpartum in mares. Reprod. Domest. Anim., v.43, p.212-217, 2008.

[2] ALBERGHINA, D.; CASELLA, S.; VAZZANA, I. et al. Analysis of serum proteins in clinically healthy goats (Capra hircus) using agarose gel electrophoresis. Vet. Clin. Pathol., v.39, p.317-321, 2010.

[3] ALBERGHINA, D.; GIANNETTO, C.; VAZZANA, I. et al. Reference intervals for total protein concentration, serum protein fractions, and albumin/globulin ratios in clinically healthy dairy cows. J. Vet. Diagn. Invest., v.23, p.111-114, 2011.

[4] BAZZANO, M.; GIUDICE, E.; FAZIO, F. et al. Serum protein electrophoresis profile during late pregnancy and early post partum period in mares. Anim. Sci. Pap. Rep., v.34, p.53-60, 2016.

[5] CAVALCANTE, P.H.; SILVA, A.C.C.; SAKAMOTO, S.M.; BLANCO, B.S. Serum proteins fractions in Brazilian-breed donkeys using Agarose gel electrophoresis. Turk. J. Vet. Anim. Sci., v.36, p.9-12, 2012.

[6] DEFINING, establishing, and verifying reference intervals in the clinical laboratory. Approved guideline. 3.ed. Wayne, PA: CLSI, 2008.

[7] ECKERSALL, P.D. Proteins, proteomics, and the dysproteinemias. In: KANEKO, J.J.; HARVEY, J.W.; BRUSS, M.L. (Eds.). Clinical biochemistry of domestic animals. 6.ed. Boston: Elsevier Academic Press, 2008. p.117-156.

[8] ECKERSALL, P.D.; HARVEY, M.J.; FERGUSON, J. et al. Acute phase proteins in canine pregnancy (Canis familiaris). J. Reprod. Fert., v.47, p.159-164, 1992.

[9] FARIA FILHO, D.E.; JARUCHE, Y.G.; LEAL, D.H.V. Classificação de coeficientes de variação na experimentação com coelhos no Brasil. Cienc. Anim. Bras., v.17, p.519-526, 2016.

[10] FONTEQUE, J.H.; CECCATTO, M.L.; BAGIO, R.M. et al. Hematological profile, total plasma protein and fibrinogen concentrations of clinically healthy adult Campeiro horses. Ciênc. Rural, v.46, p.144-149, 2016.

[11] FRANÇA, R.T.; COSTA, M.M.; MARTINS, D.B. et al. Protein profile of buffaloes of different ages. Acta Sci. Vet., v.39, p.995-999, 2011.

[12] GEFFRÉ, A.; FRIEDRICHS, K.; HARR, K. et al. Reference values: a review. Vet. Clin. Pathol., v.38, p.288-298, 2009.

[13] GRUNBERG, W.; DONKIN, S.S.; CONSTABLE, P.D. Periparturient effects of feeding a low dietary cation-anion difference diet on acid-base, calcium, and phosphorus homeostasis and on intravenous glucose tolerance test in high producing dairy cows. J. Dairy Sci., v.94, p.727-745, 2011.

[14] JACKSON, D.A.; ELSAWA, S.F. Factors regulating immunoglobulin production by normal and disease-associated plasma cells. Biomolecules, v.5, p.20-40, 2015.

[15] KANEKO, J.J. Serum proteins and the dysproteinemias. In: _____. (Ed.). Clinical biochemistry of domestic animals. 5.ed. London: Academic Press, 1997. p.117-138.

[16] KEREN, D.F.; ALEXANIAN, R.; GOEKEN, J.A. et al. Guidelines for clinical and laboratory evaluation of patients with monoclonal gammopathies. Arch. Pathol. Lab. Med., v.123, p.106-107, 1999.

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Variable	Mean ± sd	RV	CV	Percentiles
Variable	Mean ± sd	RV	CV	2.5%	50%	97.5%
TSP (g/dL)	6.75±0.59	100.00%	09%	5.73	6.75	8.00
Alb (g/dL)	2.85±0.36	42.82%	13%	2.12	2.82	3.54
Alpha1 (g/dL)	0.28±0.11	4.15%	38%	0.13	0.28	0.49
Alpha 2 (g/dL)	0.26±0.08	3.85%	31%	0.16	0.24	0.48
Beta 1 (g/dL)	0.57±0.15	8.44%	27%	0.35	0.54	0.93
Beta 2 (g/dL)	0.89±0.28	13.19%	32%	0.50	0.79	1.52
Gamma (g/dL)	1.86±0.34	27.55%	18%	1.31	1.85	2.54
A:G	0.75±0.18	-	22%	0.42	0.76	1.09

Variables	Age group				P-valor*
Variables	3 to 5 years (n= 34)	6 to 8 years (n= 34)	9 to 12 years (n= 34)	Over 13 years (n= 36)
TSP (g/dL)	6.76(0.72	6.81(0.68	6.81(0.68	6.97(0.51	ns
Alb (g/dL)	2.83(0.45	2.97(0.36	2.83(0.35	2.75(0.29	ns
Alpha1 (g/dL)	0.23(0.09^b	0.31(0.10^a	0.29(0.08^ab	0.29(0.14^ab	< 0,05
Alpha 2 (g/dL)	0.25(0.07^b	0.32(0.09^a	0.26(0.09^ab	0.22(0.05^b	< 0,05
Beta 1 (g/dL)	0.54(0.17	0.60(0.18	0.55(0.14	0.59(0.13	ns
Beta 2 (g/dL)	0.95(0.31	0.89(0.24	0.86(0.30	0.85(0.29	ns
Gamma (g/dL)	1.77(0.21^bc	1.66(0.32^c	1.88(0.34^b	2.15(0.30^a	< 0,05
A:G	0.81(0.17	0.80(0.15	0.77(0.19	0.70(0.14	ns

Variables	Mares (n= 124)	Horses (n= 14)	Mares
Variables	Mares (n= 124)	Horses (n= 14)	Non-Pregnant (n= 74)	Pregnant n= (50)
TSP (g/dL)	6.80(0.59	7.01(0.83	6.65(0.58	7.02(0.56
Alb (g/dL)	2.84(0.33	2.86(0.53	2.92(0.28	2.73(0.38
Alpha1 (g/dL)	0.28(0.11	0.30(0.09	0.25(0.09	0.33(0.12
Alpha 2 (g/dL)	0.26(0.09	0.26(0.04	0.26(0.08	0.27(0.10
Beta 1 (g/dL)	0.57(0.14	0.56(0.23	0.55(0.15	0.59(0.14
Beta 2 (g/dL)	0.92(0.28	0.74(0.23	0.90(0.30	0.89(0.25
Gamma (g/dL)	1.85(0.35	1.94(0.32	1.77(0.35	2.00(0.34
A:G	0.76(0.17	0.82(0.17	0.81(0.16	0.69(0.16

Brasil

Brasil

Serum proteinogram of the Campeiro horse

Proteinograma sérico de equinos da raça Campeiro

ABSTRACT

RESUMO

INTRODUCTION

MATERIALS AND METHOD

RESULTS

DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History