Dynamics of diabetes-associated autoantibodies in young children with human leukocyte antigen-conferred risk of type 1 diabetes recruited from the general population.

This study characterized the dynamics of islet cell antibodies (ICA), insulin antibodies (IAA), glutamic acid decarboxylase antibodies (GADA), and IA-2 antibodies (IA-2A) in 1006 children recruited from the general population due to human leukocyte antigen (HLA) DQB1-conferred risk for type 1 diabetes (T1D). By the age of 5 yr, 13.8% of the children had had one or more autoantibodies in at least one sample drawn at 3- to 12-month intervals from birth, whereas 6.1% had had one or more of the three autoantibodies to biochemically defined antigens in at least two consecutive samples. The cumulative frequencies of positivity for at least two antibodies ranged from 3.2-4.4%. Seventy-five children (7.5%) had at least once ICA, 83 (8.3%) had IAA, 46 (4.6%) had GADA, and 33 (3.3%) had IA-2A. IAA were transient more frequently than the other antibodies (P < or = 0.03) and fluctuated between positivity and negativity more often than ICA (P = 0.001). The genetically high risk children were positive for each autoantibody reactivity more often (P < or = 0.03) than the moderate risk subjects. Thirteen of the 1006 children (1.3%) presented with T1D by the age of 5 yr. The most sensitive predictors of T1D were ICA and IAA, whereas the most specific predictor was IA-2A. Positivity for at least two autoantibodies of IAA, GADA, and IA-2A had the highest positive predictive value for T1D (34%). We conclude that the frequency of various diabetes-associated autoantibodies increases at a relatively stable rate at least up to the age of 5 yr. Persistent positivity for two or more autoantibodies appears to reflect destructive progressive beta-cell autoimmunity, whereas positivity for a single autoantibody may represent harmless nonprogressive or even regressive beta-cell autoimmunity.

Signs of beta-cell autoimmunity and HLA-defined diabetes susceptibility in the Finnish population: the sib cohort from the Type 1 Diabetes Prediction and Prevention Study.

AIMS/HYPOTHESIS: To assess the role of HLA-defined genetic diabetes susceptibility in the appearance of signs of beta-cell autoimmunity in a series of children derived from the general population. METHODS: Tests for five HLA DQB1 alleles and four diabetes-associated autoantibodies were carried out on 1,584 older sibs of infants with an increased HLA-defined genetic risk of Type 1 diabetes. The DQB1 genotypes were classified into those conferring high (* 02/0302), moderate (* 0302/x; where x indicates * 0302 or a non-defined allele), low (* 0301/0302, * 02/0301, * 02/x, * 0302/0602, * 0302/0603; where x indicates * 02 or a non-defined allele) or decreased risk (other genotypes). RESULTS: Both islet cell antibodies (ICA) and GAD65 antibodies (GADA) were more frequent among the sibs with the high-risk genotype than among those with a low or decreased risk. Insulin autoantibodies and IA-2 antibodies (IA-2A) were more prevalent in the high-risk than low-risk sibs. Sibs with moderate-risk genotypes tested positive for ICA, GADA and IA-2A more often than sibs with genotypes conferring decreased risk. Autoantibody titres were also dependent on the genetic risk with high risk sibs having the highest values. Sibs carrying high-risk or moderate-risk genotypes tested positive for multiple antibodies (> or =2) more often than did the sibs with low or decreased genetic risk. CONCLUSIONS/INTERPRETATION: The data show that HLA-defined susceptibility to Type 1 diabetes has an effect on both the quality and quantity of humoral beta-cell autoimmunity in unaffected children derived from the general population.

The first signs of beta-cell autoimmunity appear in infancy in genetically susceptible children from the general population: the Finnish Type 1 Diabetes Prediction and Prevention Study.

Little is known about the timing of the etiological events and the preclinical process of type 1 diabetes during the first years of life in the general population. In this population-based prospective birth cohort study, the appearance of diabetes-associated autoantibodies as a sign of beta-cell autoimmunity and the development of type 1 diabetes were monitored from birth. Of 25,983 newborn infants, 2,448 genetically susceptible children were monitored for islet cell antibodies (ICA) at 3- to 6-month intervals. If an infant seroconverted to ICA positivity, all his/her samples were also analyzed for insulin autoantibodies (IAA), antibodies to the 65-kDa isoform of glutamic acid decarboxylase, and antibodies to the protein tyrosine phosphatase-related IA-2 molecule. Fifteen children of those who carried the high-risk genotype (2.7%) and 23 of those who carried the moderate-risk genotype (1.2%; P = 0.019) tested positive for ICA at least once. Among those who showed positivity for at least 2 antibodies during the observation period (25 of 38), IAA appeared as the first or among the first antibodies in 22 children (88%) and emerged earlier than the other antibodies (P < 0.019 or less). The first autoantibodies appeared in the majority of the children in the fall and winter (30 of 38 vs. 8 of 38 in the spring and summer, P < 0.001). These observations suggest that young children in the general population with a strong human-leukocyte-antigen-DQ-defined genetic risk of type 1 diabetes show signs of beta-cell autoimmunity proportionally more often than those with a moderate genetic risk. IAA emerge as the first detectable antibody more commonly than any other antibody specificity, implying that insulin may be the primary antigen in most cases of human type 1 diabetes associated with the DR4-DQB1*0302 haplotype. The seasonal variation in the emergence of the first signs of beta-cell autoimmunity suggests that infectious agents may play a role in the induction of such autoimmunity.