Jose Barbosa

Familial Clustering of Diabetic Kidney Disease

Diabetic nephropathy develops in less than half of all patients with diabetes. To study heredity as a possible risk factor for diabetic kidney disease, we examined the concordance rates for diabetic nephropathy in two sets of families in which both probands and siblings had diabetes mellitus. In one set, the probands (n = 11) had no evidence of diabetic nephropathy, with normal creatinine clearance and a urinary albumin excretion rate below 45 mg per day. In the other set, the probands (n = 26) had undergone kidney transplantation because of diabetic nephropathy. Evidence of nephropathy was found in 2 of the 12 diabetic siblings of the probands without nephropathy (17 percent). Of the 29 diabetic siblings of probands with diabetic nephropathy, 24 (83 percent) had evidence of nephropathy (P less than 0.001), including 12 with end-stage renal disease. No significant differences were noted between the sibling groups with respect to the duration of diabetes, blood pressure, glycemic control, or glycosylated hemoglobin levels. Logistic regression analysis found nephropathy in the proband to be the only factor significantly predictive of the renal status of the diabetic sibling. We conclude that diabetic nephropathy occurs in familial clusters. This is consistent with the hypothesis that heredity helps to determine susceptibility to diabetic nephropathy. However, this study cannot rule out the possible influences of environmental factors shared by siblings.

Diabetes mellitus associated with cystic fibrosis

The prevalence of overt diabetes mellitus and carbohydrate intolerance was studied in 448 patients with cystic fibrosis (CF). Insulin-dependent diabetes (IDDM) developed in 7.6% of patients (13 male and 21 female). Survival was significantly lower (P less than 0.01) in the IDDM-CF group, with fewer than 25% surviving to age 30 years, whereas nearly 60% of the nondiabetic CF population reached this age. A significant deterioration in CF clinical status, based on NIH score, became apparent 2 years before onset of overt IDDM (P less than 0.05 at 2 years prior, P less than 0.01 at IDDM diagnosis). Total glycosylated hemoglobin (HbA1) was significantly (P less than 0.001) higher for the total CF population (7.3% +/- 1.2%) than for the general non-CF population (6.5% +/- 0.7%), and in the IDDM-CF group (P less than 0.05) compared with normoglycemic CF control patients. Female patients had a higher mean HbA1 after 12 years of age than their male counterparts did (P less than 0.02). HBA1 did not predict the development of IDDM, but there was a weak inverse relationship between HbA1 and both NIH clinical score (r = -0.41, P less than 0.02) and standard pulmonary function tests (forced vital capacity, r = -0.25, P less than 0.01) in the general CF population. Therefore, impaired carbohydrate tolerance in CF is associated with progressive clinical deterioration.

Development of Diabetic Vascular Lesions in Normal Kidneys Transplanted into Patients with Diabetes Mellitus

We examined renal-transplant tissue from 12 diabetic and 28 nondiabetic patients who had had a renal graft for at least two years. In 10 diabetic patients arteriolar hyalinosis lesions developed in the graft. In six these lesions involved both afferent and efferent limbs of glomerular arterioles - a pathological finding virtually diagnostic of diabetes mellitus. In all cases these lesions were present within five years of transplantation. Only three of the 28 nondiabetic patients had hyaline vascular changes (P less than 0.001), which occurred only in rare vessels, did not appear within the first five years after transplantation and did not involve both afferent and efferent arterioles, One diabetic patient had nodular glomerulosclerosis. Thus, the first clearly distinguishable lesion of diabetes to occur with frequency in normal kidneys transplanted into diabetic patients is arteriolar hyalinosis.

HLA class I sequence-based typing

HLA oligogenotyping has been used successfully to characterize most phenotypically undetectable variants of class II genes. Limitations inherent to the class I system have, however, complicated the application of this and other molecular approaches to HLA class I typing. We have previously shown that HLA class II polymorphism can be analyzed by a SBT approach. Here we present a class I-SBT strategy that provides complete sequence information for the two most polymorphic exons of the HLA-A, -B, and -C alleles. HLA class I SBT is based on direct sequencing of PCR-amplified HLA-A, -B, and -C cDNAs and requires a total of six cDNA -PCR-sequencing reactions (two per locus) and 13 different oligonucleotides. Each combination of oligonucleotides per reaction results in locus-specific sequence ladders and allows identification of both alleles in heterozygotes. Application of HLA-A, HLA-B, and HLA-C SBT to 26 homozygous and 32 serologically heterozygous samples has resulted in the identification of 24 novel class I nucleotide sequences encoding 17 new major histocompatibility complex class I products. An unexpected high degree of heterogeneity was found at the HLA-C locus with 14 novel sequences. Although there was a good correlation between the serologic phenotypes and SBT results, HLA-C SBT of most HLA-C serologically homozygous samples (heterozygous for HLA-A and/or -B) revealed heterozygozity (six of eight). SBT, the first molecular typing approach that has been generalized to both class I and class II genes, may be of special interest in applications demanding high sensitivity and specificity, such as in paternity testing or in the evaluation of the effects of sequence allelism in the outcome of unrelated bone marrow transplantation.

The Development of Lesions in the Glomerular Basement Membrane and Mesangium After Transplantation of Normal Kidneys to Diabetic Patients

Renal allograft biopsies at the time of transplantation (baseline) and 2 yr later were obtained in 6 type 1 diabetic and 12 nondiabetic patients and studied for glomerular basement membrane (GBM) and mesangial changes. Diabetic patients had significantly greater GBM thickness compared with nondiabetics at 2 yr (P = 0.05, rank sum test), and the increase in GBM thickness comparing baseline and 2-yr biopsies was greater in the diabetic compared with nondiabetic patients (P = 0.005, rank sum test). Similarly, diabetic patients developed significant mesangial thickening by light microscopy while no changes were observed in nondiabetic patients (P = 0.001). Electron microscopic morphometric analysis of the percentage of total mesangium was not different on comparing diabetic and nondiabetic patients at 2 yr. There was an increase in the matrix component of the mesangium in the diabetics at this time, although this did not reach statistical significance (P = 0.06). In addition, the surface density of the peripheral glomerular capillary wall, presumably reflecting mesangial expansion, was decreased in the diabetic and unchanged in the nondiabetic patients (P = 0.005). These studies document, for the first time, the development of GBM and mesangial lesions of diabetic nephropathy in normal living related donor and cadaver kidneys transplanted into diabetic patients and support the hypothesis that these lesions are secondary to the diabetic state.

Do genetic factors play a role in the pathogenesis of diabetic microangiopathy

ConclusionsThere is no direct and conclusive evidence that genetic factors play a role in the pathogenesis of microangiopathy in diabetes. Associations between HLA antigens and complications, which would contribute conclusive evidence of a genetic contribution to the genesis of these complications, have been reported but not consistently confirmed. On the other hand, circumstantial evidence from studies of the natural history of the disease and its complications and from twin studies strongly suggest that genes do contribute to the susceptibility to small vessel disease. The most important genes providing this susceptibility are probably unrelated to HLA. Even if the total genetic contribution to susceptibility for microangiopathy turns out to be small in comparison with that provided by metabolic factors, their knowledge early in the course of the disease would serve the important role of identifying subjects in need of more intensive diabetic management to prevent vascular complications.

HLA class II “typing”: Direct sequencing of DRB, DQB, and DQA genes

Routine clinical HLA class II typing is based largely on serological and cellular methods. These methods have many drawbacks that have led to the evaluation of molecular approaches to typing, including restriction fragment length polymorphism studies and oligotyping. We present here an alternative molecular approach, sequence-based typing (SBT), that allows direct determination of the sequences of all HLA class II polymorphic genes, thus providing the most detailed information currently possible in this regard. The data presented here using SBT are based on direct sequencing of polymerase chain reaction (PCR)-amplified DRB, DQB, and DQA cDNAs using a limited number of oligonucleotides. The oligonucleotides are designed to allow simultaneous determination of allelic sequences in any heterozygote as well as characterization of DRB isotypic complexity. Two types of amplification oligonucleotides (nonconserved and/or conserved) are used for DRB typing, which involves a maximum of four simultaneous cDNA/PCR/sequencing reactions. The first of these reactions only uses conserved oligonucleotides and is designed to detect all the different DRB transcripts present in any given heterozygote; the other three reactions use nonconserved oligonucleotides and are designed to ensure the unambiguous interpretation of the most complex DRB heterozygote combinations. Characterization of DQA1 and DQB1 sequences can be performed by using conserved oligonucleotides and only involves one reaction per locus. We have applied SBT to 43 homozygous cell lines and to 38 different heterozygote combinations that had previously been serologically typed. In all cases we were able to determine the allelic composition at DRB1, DRB3/4/5 and/or DQB1, and DQA1 loci of these cell lines and subjects; our results, analyzed by blind protocol, were consistent with the serological phenotypes. SBT can be extended to class I and class III genes and is automatable. We believe that this strategy deserves further evaluation as a possible HLA typing method.

The Histocompatibility System in Juvenile, Insulin-Dependent Diabetic Multiplex Kindreds

We have histocompatibility (HLA) genotyped 24 families with two or more juvenile, insulin-dependent, ketosis-prone diabetic siblings. This criterion for family selection was used to obtain a homogeneous form of diabetes within a sibship, because diabetes appears to be a genetically heterogeneous disease. 58 diabetic and 53 nondiabetic sibs and 40 parents were studied. 55% of the diabetic pairs were concordant for both HLA haplotypes (expected 25%), 40% were concordant for one haplotype (expected 50%), and 5% were discordant for both haplotypes (expected 25%). These values are significantly different from the expected values (P < 0.001). On the other hand, the inheritance of haplotypes among the nondiabetic sibs in these families was not significantly different from the expected mendelian segregation. When comparing 20 pairs of HLA identical (sharing two haplotypes) with 15 pairs of haploidential (sharing one haplotype) diabetic sibs for the intrapair difference in age of onset of disease, we found that the HLA identical sibs were significantly more concordant for age of onset (3.9 yr difference) than the haploidential (7.3 yr difference) (P < 0.05). The same type of analysis for the difference in seasonal incidence in months revealed that the HLA indentical sibs were more concordant (1.8 mo difference) than the haploidentical sibs (3.2 mo difference) (P < 0.025). Furthermore, the HLA identical diabetic sibs were more likely to develop diabetes in the winter months (78%) than the haploidentical diabetic sibs (21%). No particular HLA haplotype or antigen seemed to be associated with any particular clinical feature. These data are compatible with the theory of genetic heterogeneity of juvenile, insulin-dependent diabetes. It is suggested that there are one or more diabetes response genes in the HLA region playing an important role in the pathogenesis of juvenile, insulin-dependent diabetes in the families studied here. It is, however, possible that other genes, not associated with the HLA complex, may play an etiologic role in some cases of juvenile, insulin-dependent diabetes, resulting in lack of association between HLA and some forms of diabetes.

Long-Term Study of Normal Kidneys Transplanted Into Patients With Type I Diabetes

We examined the rate of development of the lesions of diabetic nephropathy in transplanted kidneys residing for 6–14 yr in type I (insulin-dependent) diabetic kidney-allograft recipients. Although each recipient had end-stage diabetic nephropathy with his/her own kidneys, there was marked variability in the rate of development of mesangial expansion observed in the transplanted kidneys. The progression of glomerular pathology, including widening of the glomerular basement membrane and expansion of the mesangium, did not correlate significantly with several potential risk factors (e.g., donor source—cadaver or living related, histocompatibility match, age of the recipient or donor, age at onset of diabetes, duration of diabetes before renal failure, immunosuppressive drug dose, blood pressure, and severity of lesions of chronic rejection). However, there was a direct albeit imprecise relationship between the index of mesangial expansion at the final biopsy and the index of glycemic control (r = .61, P < .01). These observations suggest that currently unknown factor(s) may modulate the progression of diabetic renal disease, even in a population that had uniformly demonstrated nephropathy risk. Our data support the hypothesis that in addition to glycemic control per se, there are risk factors intrinsic to the kidney itself.

Insulin-dependent diabetes—Associated HLA-D region encoded determinants☆☆☆

We have studied the relative frequency of Dw specificities (defined with homozygous typing cells or primed LD (lymphocyte defined) typing reagents) associated with DR4 and DR2 in the normal and insulin-dependent diabetic population. Our findings demonstrate that there is a highly significantly increased frequency of Dw4 in DR4 positive diabetics as compared with normals and a significantly decreased frequency of Dw2 and Dw12 in the few DR2 positive insulin-dependent diabetics that we have found. In addition, we have used PLT reagents to define a new LD specificity, LD-MN2, that is associated with DR2 and is found significantly more frequently in DR2+ IDD patients than in DR2+ normals. These results suggest that determinants of import in the association between HLA-D and IDD may be more closely related to Dw than to DR.