Acessibilidade / Reportar erro

Effect of mitomocin C in eosinophilic nasal polyposis, in vivo: concentration of IL5 and GM-CSF, RT-PCR

Abstracts

Eosinophilic nasosinusal polyposis is a chronic inflammatory infection with elevated infiltration of eosinophils, which presents high rate of recurrence after surgical treatment. The continuous inflammatory process that leads to the formation of polyps requires constant clinical treatment. Contributing to the maintenance of eosinophilia are cytokines IL5 (interleukin-5) and GM-CSF (granulocyte macrophages colony-stimulating factor), which show up in elevated concentrations. These oligoproteins diminish the rate of apoptosis and prolong the survival of eosinophils. AIM: By diminishing these cytokines, the action of Mitomycin C (MMC), an antineoplasic drug which inhibits the synthesis of DNA, was studied. In a recent study the power of this drug to cause apoptosis in eosinophils, in vitro, of nasal polyps was verified. METHODOLOGY: A biopsy of the nasal polyps was undertaken in 15 patients carriers of eosinophilic nasosinusal polyposis 24 hours after applying 0.5 mg/ml of MMC during five minutes. RT-PCR (reverse transcription of polymerase chain reaction) for IL5 and GM-CSF was the method used to obtain the results. RESULTS: The comparison of the results of GM-CSF pre- and post-application of MMC, when the paired T-test was used, showed p=0.041 and for IL5 we found p<0.001. CONCLUSION: Topic use of MMC in patients with eosinophilic nasosinusal polyposis shows statistically significant reduction for GM-CSF and significant and important reduction for IL5.

nasosinusal polyposis; eosinophils; mitomycin C; interleukin 5; GM-CSF


A polipose nasossinusal eosinofílica (PNS) é manifestação de uma doença inflamatória crônica na mucosa do nariz e nos seios paranasais caracterizada por infiltração de granulócitos eosinófilos. O fator responsável pela eosinofilia e manutenção dessas células com a perpetuação do processo inflamatório e formação polipóide é objeto constante de estudos. As citocinas como IL5 (interleucina 5) e GM-CSF (fator estimulador de colônia granulócito macrófago) aumentam a sobrevida dos eosinófilos e prolongam a sua presença no tecido polipóide, diminuindo o índice de apoptose eosinofílica. OBJETIVO: Avaliar o efeito da mitomicina C - MMC - por meio de aplicação tópica em pacientes portadores de PNS eosinofílica quanto à presença de IL5 e GM-CSF. CASUÍSTICA E MÉTODOS: Quinze pacientes portadores de PNS eosinofílica foram submetidos à aplicação tópica de MMC na concentração de 0,5mg/ml, 1ml, durante cinco minutos, na cavidade nasal direita, e submetidos à biópsia para RT-PCR 24hs após. O grupo-controle foi a cavidade nasal esquerda. O perfil de citocinas foi analisado para IL5 e GM-CSF. RESULTADOS: A comparação dos resultados de GM-CSF pré e pós-uso de MMC quando usamos o teste t pareado apresenta p=0,041. A comparação para IL5 resulta em p < 0,001. CONCLUSÃO: O uso de MMC em pacientes com PNS mostra redução com significância estatística par GM-CSF e importante significância para IL5.

polipose nasossinusal; eosinófilos; mitomicina c; interleucina 5; GM-CSF


ORIGINAL ARTICLE

Effect of mitomocin C in eosinophilic nasal polyposis, in vivo: concentration of IL5 and GM-CSF, RT-PCR

Mirian Cabral Moreira de CastroI; Evaldo AssunçãoII; Mariana Moreira de CastroIII; Ricardo Nascimento AraújoIV; Roberto Eustáquio GuimarãesV; Flávio Barbosa NunesVI

IMSc Surgery Student – Medical School - UFMG – Professor at the School of Medical Sciences, preceptor of Medical Residence – UFMG University Hospital and Santa Casa de Misericórdia Hospital

IIAssociate Professor, assistant Professor – Department of Parasitolgy - Universidade Federal de Minas Gerais

IIIOtolaryngology resident of the University Hospital - UFMG

IVPhD in parasitology - UFMG, Post-doctorate student in parasitology - UFMG

VAssociate Professor, Assistant Professor of the Department of Ophthalmology, Otolaryngology and Speech Therapy - Universidade Federal de Minas Gerais

VIMSc in Otolaryngology by the Paulista School of Medicine, Preceptor of the Medical Residence at the University Hospital - UFMG

Mailing address Mailing address: Mirian Cabral Moreira de Castro Rua Padre Rolim 515 8º andar Bairro Funcionários Belo Horizonte MG 30130-090 Telefax: (0xx31) 3241-2451 E-mail: miriancabralmc@hotmail.com

SUMMARY

Eosinophilic nasosinusal polyposis is a chronic inflammatory infection with elevated infiltration of eosinophils, which presents high rate of recurrence after surgical treatment. The continuous inflammatory process that leads to the formation of polyps requires constant clinical treatment. Contributing to the maintenance of eosinophilia are cytokines IL5 (interleukin-5) and GM-CSF (granulocyte macrophages colony-stimulating factor), which show up in elevated concentrations. These oligoproteins diminish the rate of apoptosis and prolong the survival of eosinophils.

AIM: By diminishing these cytokines, the action of Mitomycin C (MMC), an antineoplasic drug which inhibits the synthesis of DNA, was studied. In a recent study the power of this drug to cause apoptosis in eosinophils, in vitro, of nasal polyps was verified.

METHODOLOGY: A biopsy of the nasal polyps was undertaken in 15 patients carriers of eosinophilic nasosinusal polyposis 24 hours after applying 0.5 mg/ml of MMC during five minutes. RT-PCR (reverse transcription of polymerase chain reaction) for IL5 and GM-CSF was the method used to obtain the results.

RESULTS: The comparison of the results of GM-CSF pre- and post-application of MMC, when the paired T-test was used, showed p=0.041 and for IL5 we found p<0.001.

CONCLUSION: Topic use of MMC in patients with eosinophilic nasosinusal polyposis shows statistically significant reduction for GM-CSF and significant and important reduction for IL5.

Key words: nasosinusal polyposis, eosinophils, mitomycin C, interleukin 5, GM-CSF.

INTRODUCTION

Naso-Sinus Polyposis (NSP) – eosinophylic NSP – is a chronic proliferative inflammatory disease that affects the nasal and nasal sinuses mucosa, and is characterized by a benign polypoid degeneration (Figure 1). It is usually bilateral, has its incidence peak on the fourth decade of life and affects 2.7% of the population, with a 2.2:1 male/female ratio. It is strongly associated to asthma; 1/3 of eosinophilic NSP patients have asthma, therefore, the complete exam of the respiratory tract should be a routine. It is also related to NAER (non-allergic eosinophilic rhinitis), aspirin intolerance, alergic fungal sinusitis and Churg-Strausss syndrome1,2.


They are Histologically characterized by eosinophilic granulocytes of which the pathogenic mechanism is not entirely known. They also bear morphologic alterations such as nasal membrane hyperplasia, irregularity of gland distribution, squamous metaplasia and edema (Figure 2)3,4.


Although it has been related to IgE mediated hypersensitivity, or nasal allergy, studies have shown that allergy is only one possible cause or a contributing factor5-7. Eosinophil and polyp structural cells secrete cytokines that maintain the inflammation process and the Eosinophil build up constant. 8 Cytokines such as IL5 and GM-CSF increase eosinophil survival and prolong their presence within the polypoid tissue, reducing the apoptosis rates of these cells9-12.

Eosinophils express CD40 receptor for this GM-CSF and CD40L autocrine production and they are expressed by T CD4 cells that are present in eosinophilic NSP13.

The high IL5 concentration found on eosinophilic NSP suggests an autocrine effect for this cytokine in eosinophil activation, there still is a strong relation between IL5 and ECP (eosinophilic cationic protein)10,14.

This cytokine increase is related to the genetic aspect of the NSP eosinophilic cells5.

Most of the treatment available is based on the use of systemic steroids for a short duration and topical steroid for a longer period, besides surgery15.

MMC is an antineoplastic agent produced by the Streptomyces caespitosus that has been used as antiproliferative agent in the 0.4mg/ml concentration. When used after surgery, its action on fibroblasts leads to a reduction in scar tissue formation. It has a time-dependent action e its application for 5 minutes has a measurable effect on cell morphology and proliferation for up to 36 days in vitro16. MMC mechanism of action is based on the selective induction of DNA synthesis, recombination and exchange of "sister" chromatin. Its association with other anti-tumoral drugs leads to an increase in its cytotoxic effect by increasing apoptosis induction17-19.

Crosara et al. (2004) showed that MMC is efficient in inducing the apoptosis of eosinophils present in the stroma of eosinophilic nasal polyps in vitro. Paired studies with nine cultivated samples were carried out. The polyps were treated with 0.4mg/ml for five minutes and were dyed with hematoxylin eosine15.

In topical use, this drug has been used in ophthalmology, otology and laryngology without systemic toxicity, thus being considered safe. It does not cause bleeding, necrosis or infection when used in external acriocistorhinostomy or permanent eyelash lesions in concentrations of up to 1mg/ml16,18,20-27.

This study aims at assessing MMC action, in vivo, in patients with eosinophilic NSP through IL5 and GM-CSF analysis, pre and 24hs post application, using RT-PCR (reverse transcription in polymerase chain reaction).

MATERIALS AND METHODS

This investigation was made up of eosinophilic NSP patients who agreed to participate in the study, after approval by the Research Ethics Committee. The variables were made up of GM-CSF and IL5 profiles. 15 patients were studied, 6 women and 9 men. Their ages varied from 30 to 57 years.

As inclusion criteria, we used: presence of eosinophilic NSP and no aspirin intolerance. Eosinophilic polyps were considered when tissue eosinophylia as greater then 30% among inflammatory cells, determined by finding at least four eosinophils in each large magnification microscopic field28. Patients with previous history of aspirin intolerance, who underwent previous surgery or severe steroid-dependent asthma patients were excluded.

The patients selected underwent MMC application on the right nasal cavity polyps in the concentration of 0.5mg/ml in a cotton ball wet with 1 ml of the drug, where it remained for five minutes. The left nasal cavity was the control-group, considered as pre-use.

PCR biopsies after 24h of MMC use were made in the right nasal cavity and, following that, in the left nasal cavity as well. Tissues collected had average size of 10mm, were then immediately taken to the University Immunology lab where they remained stored at 80 degrees below zero.

The cytokines profile was checked on the polypoid tissue through reverse transcription in polymerase chain reaction (RT-PCR) for IL5 and GM-CSF.

Primer sequence used in the PCRs

Gene Forward Reverse GM-CSF AGAAATGTTTGACCTCCAGGA TTGCACAGGAAGTTTCCG IL 5 CTGAGGATTCCTGTTCCTGT CAACTTTCTATTATCCACTC

The PCR products were analyzed by electrophoresis in silver dyed 8% polyacrylamide gel. The gels were photographed using the AlphaDigiDoc 1201 photo-documentation system, and the PCR resulting bands for each sample were analyzed by densitometry, using the AlphaEaseFC software version 3.3.0 (Alphalnnotech) (Figure 3). This software calculates the IDV - Integrated Density Value for each band, and it is defined as the pixel intensity in the region outlined by the band, subtracted from the pixel intensity of the bottom color of the gel band.


RESULTS

Regarding the values obtained for IL5, in Figure 4 we see the box-plot distribution chart before and after MMC use. We see that 75% (upper part of the box) of IL5 values after MMC are below 3,000 while almost 100% (lower chart line before) of the IL5 pre MMC values are above this value.


Comparing the IL5 average pre and post, using the paired t test we saw a p<0.001, indicating important statistical significance.

In relation to the GM-CSF values on Figure 5, we see the box-plot chart of the GM-CSF pre and post MMC application distribution values and notice that 75% (upper box) of GM-CSF values are below 15,000 while only 50% of the GM-CSF pre MMC values are below this threshold (middle line of the pre MMC chart). The average pre and post GM-CSF comparison using the paired t test, showed a p =0.041. Thus, the observed difference does bear statistical significance.


Figure 6 shows GM-CSF and IL5 percentage reduction in the distribution values box-plot chart. We can see that practically over 75% of patients had an IL5 reduction above 60%, because the box line is somewhat below this value and that 75% of the patients had a GM-CSF reduction below 60%, because the upper box line is somewhat below this value.


Table 1 shows the Pearson’s correlation coefficient for IL5 and CM-CSF variation percentage comparison with the continuous variables.

No statistically significant correlation was observed, in other words, the IL5 and GM-CSF percentage variation reduction was not followed suit by the variation of any of the other variables.

DISCUSSION

The participation of polymorph nuclear cells in the nasal mucosa epithelial interface and in other nose diseases is well understood. The increase in cytokine concentrations proves its inflammatory nature. Eosinophils are sources of interleukins that bear autocrine and modulator effect on the function of other cells14. The continuity of the inflammatory response seen in the eosinophylic NSP is related to cytokines such as IL5 and GM-CSF which increase survival and reduce the eosinophil apoptosis rate7,8,10-12.

Therefore, they regulate proliferation and cell activation, broadening local immune response and polyp formation. Eosinophils express IL5 in all eosinophylic NSP and, approximately 30% of the eosinophils have genetic expression for GM-CSF, with evidences of autocrine effect for these citokines14. The eosinophil clearance would be a mechanism to reduce the inflammatory process. The cytokine production is related to the tissue cell phenotype, and numerous studies show the key participation of IL5 and GM-CSF in maintaining the inflammatory activity. Therefore, blocking these cytokines would be a therapeutic way to improve this condition. One single MMC application for five minutes has a measurable effect on cell morphology and proliferation for up to 36 days in vitro16.

Crossara et al. Showed that MMC is efficient in inducing eosinophil apoptosis when these are present in the stroma of eosinophylic nasal polyps. A paired study with nine cultivated samples was carried out and we observed that the MMC treated cultures presented 12-hour apoptosis rate significantly higher in relation to the control group (p<0.001)15.

MMC proved to have inhibitory action on DNA synthesis, inhibiting the proliferation of many cell lines. Kim et al. showed that its anti human-cultivated-fibroblasts effect may be mediated not only by the antiproliferative action, but also by the degree of apoptosis induced21.

Our goal in this study was to show MMC action in reducing the concentration of major cytokines that act in maintaining the eosinophylic NSP inflammatory process. Such study has not yet been found in the medical literature.

The paired t test showed that the post MMC GM-CSF values were significantly lower than the pre values (p=0.041). Comparing IL5 values pre and post MMC, we found one important reduction: the medication was efficient in reducing the concentration of these substances. Comparing the percentage with the other variables, we did not observe any variable that would present significant correlation.

MMC may be an option in the pos-surgical treatment of eosinophylic NSP. Further studies are necessary to better use this drug against this disease.

CONCLUSION

As to the action of MMC over the main cytokines involved in NSP inflammatory process and in relation to the age and percentage of eosinophils, we concluded that:

1. The IL5 post MMC use values were lower than pre MMC use, with important statistical significance;

2. The GM-CSF post MMC use values were lower than pre MMC use, with statistical significance.

REFERENCES

Paper submitted to the ABORL-CCF SGP (Management Publications System) on August 21st, 2005 and accepted for publication on September 23rd, 2005.

Award winning paper in the IV Triological Meeting of 2005

Department of Ophthalmology, Otolaryngology and Speech Therapy of the Universidade Federal de Minas Gerais. Prof. Evaldo Nascimento Laboratory of Immunology.

  • 1
    Berstein JM. Pólipos Nasais: determinando a Causa Estabelecendo o Tratamento. J Respir Diseases 1998;2: 4-9.
  • 2
    Settipane GA. Nasal polyps and systemic diseases In: Schatz M, Zeiger RS, Settipane GA. Nasal manifestations of systemic diseases Providence: Oceanside Publ 1991a; 43-51.
  • 3
    Coste A, Rateau JG, Roudot-Thoraval F, Chapelin C, Gilain L, Poron F, Peyègre R, Bernaudin J, Escudier E. Increased epithelial cell proliferation in nasal polyps. Arch Otolaryngol Head Neck Surg 1996 ;122: 432-6.
  • 4
    Pawankar R. Nasal polyposis: An update. Curr Opin Allergy Clin Immunol 2003;3:1-6.
  • 5
    Bernstein JM, Gorfien J, Noble B. Role of allergy in nasal polyposis: a review. Otolaryngol Head Neck Surg 1995;113: 724-32.
  • 6
    Sánchez-Segura A, Brieva JA, Rodríguez C. Regulation of immunoglobulin secretion by plasma cells infiltrating nasal polyps Laryngoscope 2000;110: 1183-8.
  • 7
    Hirschberg A, Jókúti A, Darvas Z, Almay K, Répássy G, Falus A. The pathogenesis of nasal polyposis by immunoglobulin E and interleukin-5 is completed by transforming growth factor-beta1. Laryngoscope 2003;11(1)3: 120-4.
  • 8
    Shin SH, Lee SH, Jeong HS, Kita H. The effect of nasal polyp epithelial cells on eosinophil activation. Laryngoscope 2003;113:1374-7.
  • 9
    Jamal A, Marant AGD. Atopy and nasal polyposis. J Laryngol Otol 1987;101: 355-8.
  • 10
    Allen JS, Eisma R, Leonard G, Kreutzer D. Interleukin-3 interleukin-5 and granulocyte-macrophage colony-stimulating factor expression in nasal polyps. Am J Otolaryngol 1997;18: 239-46.
  • 11
    Bachert C, Genmann M, Hauser U, Rudack C. IL-5 synthesis is upregulated in human nasal polyp tissue. J Allergy Clin Immunol 1997;99: 837-42.
  • 12
    Gevaert P, Bachert C, Holtappels G, Novo CP, van der Heyden J, Fransen L, Depraetere S, Walter H, van Cauwenberge P, Tavernier J. Enhanced soluble interleukin-5 receptor alpha expression in nasal polyposis. Allergy 2003;58: 371-9.
  • 13
    Walsh GM. Eosinophil apoptosis: mechanisms and clinical relevance in asthmatic and allergic inflammation. Br J Haematol 2000;111: 61-7.
  • 14
    Jankowski R. Eosinophils in the pathophysiology of nasal polyposis. Acta Otolaryngol 1996;116:160-3.
  • 15
    Crossara PFTB, Nascimento E, Sobrinho SC, Vasconcelos AC, Guimarães RES, Becker HMG, Calosimo EA, Nunes FB. Efeito da mitomicina C em cultura de estroma de pólipos nasais eosinofílicos: indução de apoptose em eosinófilos. Rev Bras Otorrinolaringol 2004;70:658-63.
  • 16
    Ingrams DR, Volk MS, Biesman BS, Pankratov MM, Shapshay SM. Sinus surgery: does mitomycin C reduce stenosis? Laryngoscope 1998;108: 883-6.
  • 17
    Stream SA, Vanlleuwen RN. Use of mitomycin-C for maintaining myringotomy patency. Otolaryngol Head Neck Surg 2000;122:8-10.
  • 18
    Iliev ME, van der Zypen E, Frankhauser F, England C. Transconjunctival application of mitomycin C in combination with laser sclerostomy ab interno: a long term morphological study of the post operative healing process. Exp Eye Res 1997;64:1013-26.
  • 19
    Kraut A, Drnovsek-Olup B. Instillation of mytomicin C after recurrent pterygium surgery. Eur J Ophtalmol 1996;6: 264-7.
  • 20
    Khaw PT, Doyle JW, Sherwood MB, Grierson I, Schultz G, McGorray S. Prolonged localized tissue effects from 5-minute exposures to fluorouracil and mitomycin C Arch Ophtalmol 1993;111: 263-7.
  • 21
    Kim J, Kim S, Song I, Kim I. Mitomycin C-induced apoptosis in cultured human tenon’s capsule fibroblasts. Korean J Ophthalmol 1999;13:7-15.
  • 22
    Schwartz GK, Haimovitz-Friedman A, Dhupar SK, Ehleiter D, Maslak P, Lai L, Loganzo F, Kelsen DP, Fuks Z, Albino AP. Potentiation of apoptosis by treatment with the protein kinase C-specific inhibitor safingol in mitomycin C- Treated gastric cancer cells. J Nat Cancer Inst 1995;87:1394-9.
  • 23
    Becker CG. Tratamento cirúrgico da otite média com efusão: tubo de ventilação versus aplicação tópica de mitomicina C. Tese (doutorado). Faculdade de Medicina Universidade Federal de Minas Gerais; 2003.
  • 24
    Rahal A, Peloquin L, Ahmarani C. Mitomycin C in sinus surgery: preliminary results in a rabbit model. J Otolaryngol 2001;30:1-5.
  • 25
    Chung JH, Cosenza MJ, Rahbar R, Metson RB. Mitomycin C for the prevention of adhesion formation after endoscopic sinus surgery: a randomized controlled study. Otolaryngol Head Neck Surg 2002;126:468-74.
  • 26
    Holland BW, McGuirt WF. Surgical management of choanal atresia: improved outcome using mitomycin. Arch Otolaryngol Head Neck Surg 2001;127:1375-80.
  • 27
    Liao SL, Kao SC, Tseng JH, Chen MS, Hou PK. Results of intraoperative mitomycin C application in dacryocystorhinostomy. Br J Ophthalmol 2000;84:903-6.
  • 28
    Ingels V, Durdurez JP, Cuvelier C, Cauwenberge PV. Nasal biopsy is superior to nasal smear for finding eosinophils in nonallergic rhinitis. Allergy 1997;52:338-41.
  • Mailing address:

    Mirian Cabral Moreira de Castro
    Rua Padre Rolim 515 8º andar Bairro Funcionários
    Belo Horizonte MG 30130-090
    Telefax: (0xx31) 3241-2451
    E-mail:
  • Publication Dates

    • Publication in this collection
      08 Aug 2006
    • Date of issue
      Feb 2006

    History

    • Accepted
      23 Sept 2005
    • Received
      23 Sept 2005
    ABORL-CCF Associação Brasileira de Otorrinolaringologia e Cirurgia Cérvico-Facial Av. Indianápolis, 740, 04062-001 São Paulo SP - Brazil, Tel./Fax: (55 11) 5052-9515 - São Paulo - SP - Brazil
    E-mail: revista@aborlccf.org.br