T cell recognition of Mls. T cell clones demonstrate polymorphism between Mlsa, Mlsc, and Mlsd

The determinants encoded by the minor lymphocyte stimulating locus (Mls) are defined as determinants that induce strong T cell proliferative responses in primary mixed lymphocyte reactions. Although the Mls locus was originally described as having four alleles, a, b, c, and d, a number of recent observations have led several investigators to challenge the idea that Mls is truly a polymorphic system. To better define this system of determinants recognized at high frequency by T cells, the present studies were undertaken to evaluate the polymorphism of Mls products. In the present study, the in vitro proliferative responses of Mlsa- and Mlsc-specific T cell clones were employed to analyze Mls products. The identification of determinants recognized by Mlsa- and Mlsc-reactive clones was established by the pattern of responses to stimulators derived from congenic strains, recombinant inbred strains, and backcross mice. T cell clones and unprimed T cells gave concordant responses that confirmed the Mlsa or Mlsc specificity of the cloned populations. With the use of these two sets of Mls-specific T cell clones, the existence or absence of polymorphism of Mls-encoded gene products was examined. It was found that Mlsa-specific cloned T cells responded to Mlsa but not Mlsc stimulators, whereas Mlsc-specific clones responded to Mlsc but not Mlsa. This reciprocal pattern of specificity indicates that the Mls system as currently defined is therefore truly polymorphic. In addition, it was observed that both Mlsa- and Mlsc-specific clones were stimulated by Mlsd stimulators. In particular, the possibility that Mlsa and Mlsc are not alleles but products of different loci and that Mlsd strains are those that express both Mlsa and Mlsc is considered.     

Nonresponsiveness to Mlsd in F1 hybrid mice carrying Mlsa and Mlsc genes

Neither the biological function nor a basic understanding of the enigmatic chromosome 1-encoded Mls locus of the mouse has yet been uncovered despite extensive investigations. The present report is a continuation of our genetic analyses of the Mls locus in an attempt to better define the system. Data presented here indicate that in contrast to cells of mice expressing either the Mlsa or Mlsc allele which respond in mixed leukocyte reactions to cells expressing the Mlsd allelic products, cells from (Mlsa X Mlsc)F1-hybrid mice do not. In addition, the nonresponder phenotype appears to segregate as a single autosomal genetic system in backcross animals. These findings fail to support two recently advanced hypotheses: first, that the Mls locus is nonpolymorphic, or second, that the Mls locus controls differential expression of Ia antigenic determinants. Although the mechanism by which a (responder X responder) converts to a nonresponder remains unknown, three models involving gene complementation are discussed.     

Activation requirements of cloned inducer T cells. III. Need for two stimulator cells in the response of a cloned line to Mls determinants

To gain insight into the nature of Mls determinants, we examined the stimulator cells responsible for the activation of inducer T cell clones by Mls determinants. Two types of clones responding to Mls determinants were identified. One type responded to purified B cells, but not to splenic adherent cells (SAC), from mice bearing Mls stimulatory determinants. The other type of Mls-reactive T cell clone, including the representative clone Ly1-N5, demonstrated a vigorous response to unfractionated spleen cells, but showed little or no response to B cells alone or to SAC alone from mice bearing the Mlsa or Mlsd stimulatory determinant. The response of these clones to Mls determinants required stimulation by two cell types. The failure of clone Ly1-N5 to respond to Mlsa-bearing B cells was reversed by the addition of SAC taken from mice bearing the Mlsa allele. In addition, SAC from mice bearing the nonstimulatory Mlsb allele could synergize with B cells from Mlsa-bearing animals. B cells were required to provide the Mlsa determinant, because the combination of Mlsa-bearing SAC and Mlsb-bearing B cells did not activate the clone. The response of clone Ly1-N5 to Mls is restricted by Ia determinants (shared by H-2b, H-2d, and H-2k haplotypes but not by the H-2q haplotype). The permissive H-2 alleles can be present either on the stimulator B cell or on the SAC. The optimal response of the clone was obtained by using B cells bearing Mlsa and the permissive Ia epitopes. However, a significant response of the clone to B cells bearing Mlsa but an inappropriate Ia (Iaq) was also seen in the presence of SAC bearing the nonstimulatory Mlsb allele but the permissive Ia epitopes.     

The Mlsd-defined primary mixed lymphocyte reaction: a composite response to Mlsa and Mlsc determinants

Considerable disagreement exists among immunologists regarding the polymorphic nature of the murine Mls system. An estimate of the capacity of a given putative Mls allelic gene product expressed on a stimulator population to elicit proliferation of H-2-compatible Mls-disparate unprimed T cells may vary widely among different groups of investigators. This laboratory has shown previously that preactivation of B lymphocytes in a splenocyte stimulator population by exposure to goat anti-mouse IgD (GaMD) before irradiation dramatically enhanced the in vitro presentation not only of the strongly stimulatory (and highly cross-reactive) Mlsa and Mlsd, but also the more poorly stimulatory Mlsc specificity. Therefore, by the use of GaMD-treated splenocytes that optimally present the various Mls non-H-2 stimulatory epitopes, we attempted in this study to obtain a clearer understanding of Mls polymorphism by re-examining the conflicting claims associated with the mixed lymphocyte reaction (MLR) stimulatory capacity of different Mls specificities. Among H-2k responder cells of the Mls null, Mlsa, Mlsb, or Mlsd genotypes, only T cells from Mlsd-bearing CBA/J mice did not respond to Mlsc determinants present on GaMD-treated C3H/HeJ stimulator cells. Crossing CBA/J with an Mlsc-responsive mouse strain yielded an F1 animal in which nonresponsiveness to Mlsc was dominant. Although Mlsa (AKR/J) and Mlsc (C3H/HeJ) parental T cells both proliferated vigorously to Mlsd (CBA/J) stimulator cells, the Mlsa/c (AKR X C3H)F1 T cells responded poorly to GaMD-treated Mlsd stimulator cells. In addition, Mlsd (CBA/J) T cells were nonresponsive to Mlsa (AKR/J), Mlsc (C3H/HeJ), and Mlsa/c (AKR X C3H)F1 GaMD-treated stimulator cells. Because Mlsa (AKR/J) and Mlsc (C3H/HeJ) specificities are mutually stimulatory, at least limited polymorphism must exist in the Mls system. However, because Mlsa/c (AKR X C3H) and Mlsd (CBA/J) specificities are mutually nonstimulatory, T cell proliferation in an Mlsd-defined primary MLR is most likely due to a composite response to Mlsa and Mlsc epitopes present on CBA/J stimulator cells.     

Bidirectionality of mixed lymphocyte stimulation (Mls) response. Effects of Mlsb stimulator cells on Mlsa helper cells

The activation of BALB/c lymphocytes in the mixed lymphocyte reaction to Mls-disparate APC has been shown to encompass up to 20% of the mature resting helper T lymphocyte population. In addition to these overtly Mls-responsive cells, our studies have revealed a second population that respond to the Mls difference of DBA/2 spleen cells in conjunction with the mitogen Con A. This part of the Mls response is therefore latent. As mitogen and Mls-stimulating effect act in synergy, it is likely that both stimuli act on the same cell, and hence the Mls effect can be regarded as a regulatory interaction between APC and Th cell. By use of congenic BALB.Mlsa mice, the regulatory effect has been mapped to the Mls locus. The regulatory influence has also been demonstrated in DBA/2 Th cells (Mlsa) stimulated simultaneously with mitogen and Mls-disparate (Mlsb) APC, consistently causing inhibition of mitogen-induced proliferation in this reverse Mls direction. This antagonistic effect has also been linked to the Mls locus. We conclude that the Mls reaction governed by the a and b alleles is bidirectional, producing synergy with class II-dependent activation signals in the direction of Mlsa----Mlsb, and antagonism in the direction Mlsb----Mlsa. Both the classical Mls and the reverse Mls effects have been demonstrated at the clonal level. These results are in accord with the previously proposed hypothesis that the Mls molecule serves as a down-regulatory stimulus in the activation of Th cells. Mls responses of Mlsb T cells are explained as the consequence of a diminished down-regulation by Mlsa APC. Conversely, the reverse Mls response described here can be considered a consequence of inordinately high down-regulation of the Mlsa T cell responses by Mlsb APC.     

Isolation and characterization of an I-A-restricted T cell clone with dual specificity for poly(Glu60Ala30Tyr10) (GAT) and Mlsa,dl

We have isolated a BALB/c (H-2d, Mlsb) T cell clone (JTL-G12) specific for the synthetic polypeptide antigen poly(Glu60Ala30Tyr10) (GAT) in the context of self I-A determinants and for Mlsa,d antigens in the absence of GAT. JTL-G12 proliferation in response to GAT was mapped to the Kd, I-Ad subregions by using inbred H-2 congenic and recombinant strains. In addition, monoclonal antibody directed against I-Ad but not Kd or I-As determinants blocked JTL-G12 proliferation in response to GAT presented by syngeneic splenocytes, indicating I-A restriction. The Mls cross-reactivity of this clone was verified by using a panel of inbred strains bearing the Mlsa,b,c,d alleles and by using BXD recombinant inbred strains bearing the Mlsa allele or the Mlsb allele. All of the Mlsa BXD strains of the H-2d or H-2b haplotypes stimulated JTL-G12 in the absence of GAT, whereas all of the Mlsb BXD strains were nonstimulatory. This response pattern is in complete accordance with recognition of the Mlsa determinant encoded by Mls or closely linked loci on chromosome 1. JTL-G12 proliferation in response to GAT/I-Ad and Mlsa,d determinants could be blocked with a monoclonal antibody (GK1.5) directed against L3T4, a structure involved in class II major histocompatibility complex antigen recognition. These results suggest that antigen/class II responsiveness, Mls reactivity, and expression of L3T4 can be properties of a single T cell population.     

The immunobiology of the T cell response to Mls-locus-disparate stimulator cells. I. Unidirectionality, new strain combinations, and the role of Ia antigens

The primary mixed lymphocyte reaction of T cells to Mls-locus-disparate stimulator cells differs from that to non-self Ia antigens in several respects. In the present experiments, the unidirectional nature of this response is shown in several strain combinations, including the newly detected Mlsa and Mlsa-like alleles expressed by strains PL/J, RF/J, and SM/J. All of these strains stimulate MHC-identical T cells strongly. In addition, they stimulate a variety of cloned T cell lines specific for Mlsa,d, which can thus be shown to respond to Mlsa,d stimulators of the H-2b,d,k,u, and v haplotypes. Although these results suggest that primary T cell responses to Mlsa,d are unlikely to be MHC restricted, these primary responses are readily inhibited by monoclonal antibodies specific for the I-A and especially the I-E products borne by the stimulator cells, as well as by monoclonal antibodies specific for L3T4a on the responding T cells. This effect of anti-Ia antibodies is not overcome by exogenous interleukin 1. Thus, I-A and especially I-E molecules are centrally involved in the unidirectional primary T cell response to the potently stimulating Mlsa and Mlsd alleles expressed by cells of several different MHC haplotypes.     

T cell recognition of Mlsc,x determinants

Among a large number of cow insulin-specific T cell clones derived from both C57BL/10 and B10.A strains, several were found to react to non-MHC-linked gene products of a number of allogeneic strains. The stimulatory moiety for three of these clones correlates, in part, with expression of Mlsc, as defined by mouse strains C3H/HeJ and A/J. In addition, all three of these clones are stimulated by cells from strain PL/J, which has the poorly defined Mlsx allele. The data strongly suggest that Mlsx may, in fact, be Mlsc or is, at least, highly cross-reactive with Mlsc. Segregation analysis by using (B10.D2 X PL/J)F2 mice demonstrates that the Mlsx gene is genetically independent of the Mlsa linked Ly-9 marker on chromosome 1. Further studies with the use of these Mlsc,x-reactive clones reveal that they also recognize a gene product present in many mouse strains including DBA/2 which were previously phenotyped as Mlsa. However, testing of BxD recombinant inbred lines excludes Mlsa as being the stimulatory moiety. We therefore propose reclassification of the Mls phenotypes of several mouse strains based upon a two-locus model for Mls.     

Characterization of a new minor lymphocyte stimulatory system. I. Cluster of self antigens recognized by "I-E-reactive" V beta s, V beta 5, V beta 11, and V beta 12 T cell receptors for antigen.

In the mouse, two sets of V beta gene products have been shown to be associated with T cell recognition of endogenous self Ag. One of these is the set of V beta associated with T cell reactivities to stimulatory Mls gene products, Mlsa (V beta 6, V beta 8.1, V beta 9) or Mlsc (V beta 3); another is the set of V beta, such as V beta 5, V beta 11, V beta 12, or V beta 17a, which were originally found to be related to I-E recognition. Although the Mls system has been well characterized, little is known about the nature of the ligands for the second set of V beta. In this work, we describe the evidence that the natural ligand or ligands of V beta 5, V beta 11, and V beta 12 may be novel Mls determinants that are recognized by naive T cells at a high precursor frequency and function as the ligand for clonal deletion of self-reactive T cells by negative selection. However, surprisingly, unlike the conventional Mls system, in which all V beta associated with Mlsa recognition or Mlsc recognition are uniformly deleted in those animals expressing the relevant Mls type, expression of these three V beta segregates independently among strains. Based on these observations, the nature of T cell recognition for this new Mls gene product(s) is discussed.     

Geographical variation of the alleles at the two prolamin loci, Pro1 and Pro2, in foxtail millet, Setaria italica (L.) P. Beauv

Allelic variation at the two prolamin loci (Pro1 and Pro2) and its geographical distribution in 560 local cultivars of foxtail millet (Setaria italica) mainly from Eurasia were studied using SDS-polyacrylamide gel electrophoresis (SDS-PAGE). Genetic analysis of a newly detected polymorphic band, band 6, indicated that it is controlled by an allele at the Pro2 locus, which was designated as Pro2f. Two alleles (Pro1a and Pro1null) at the Pro1 locus and six alleles (Pro2a, Pro2b, Pro2c, Pro2d, Pro2e and Pro2f) at the Pro2 locus were detected among the cultivars examined. Although the frequency of the Pro1a allele varied from 0% in the Nansei islands of Japan and Africa to 66% in Afghanistan, no apparent trend was observed in geographical distribution. In contrast, two common alleles at the Pro2 locus, Pro2b and Pro2f, had clear differential geographical distribution. The Pro2b allele was most frequent in Europe and decreased in frequency eastwards. The Pro2f allele occurred frequently in subtropical and tropical regions including the Nansei islands of Japan, the Philippines, Nepal, India, Pakistan and Africa. All eight alleles at the Pro1 and Pro2 loci occurred in China, suggesting China is a center of diversity. The origin of geographical differentiation of local cultivars into a "tropical group" characterized by the Pro2f allele and other genes was discussed.     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. II. Significance of MHC antigens in anti-Mls tolerance

Specificity of anti-Mlsa tolerance induced in BALB/c (H-2d, Mlsb) neonates was investigated by a popliteal lymph node (PLN)-swelling assay for the local graft-versus-host (GVH) reaction by injecting tolerant thymus cells into the footpads of several types of F1 hybrid mice. When thymus cells were obtained from 1-week-old normal BALB/c, they evoked enlargement of PLNs of (BALB/c X DBA/2)F1 (H-2d, Mlsb/a) [CDF1] recipients and of other hybrid recipients, heterozygous in Mlsa,c,d alleles, irrespective of the major histocompatibility complex (MHC) haplotypes. The same thymus cells did not cause the response in MHC-heterozygous F1 hybrids when the hybrids were homozygous in Mlsb, identical with BALB/c mice. Therefore, the PLN response to Mls antigens, known to be closely associated with MHC-class II antigens, was not directed to the class II antigens themselves. This enabled us to examine the effects of MHC on tolerance induction to the Mls antigens. When BALB/c neonates were injected with CDF1 bone marrow cells, complete tolerance to Mlsa-H-2d antigens of CDF1 cells was induced in the thymus, while responsiveness to Mlsa antigens in the context of H-2k and H-2b antigens, was not affected. This indicates MHC-restriction of neonatal tolerance to Mls antigens. Furthermore, when Mls and H-2-heterozygous (BALB/c X AKR)F1 (H-2d/k, Mlsb/a) bone marrow cells served as the tolerogen, thymus cells of BALB/c neonates were also tolerized to Mlsa-H-2k antigens as well as to Mlsa-H-2d antigens, which suggests the involvement of MHC, probably class II antigens of tolerance-inducing cells.     

Multi-gene/allele control of Mls b of CBA/H

Festenstein originally described the Mls locus as a single dominant autosomal gene with four alleles which mapped in the 13th linkage group of chromosome 1. We subsequently presented evidence indicating that the mixed leukocyte reaction (MLR) stimulatory products of DBA/2 and CBA/J were controlled by two independently segregating Mls loci and that Mls of C3H was in fact a composite of three independently segregating loci. Recently, Mls ^d of CBA/J was shown to be composed of Mls ^a of AKR and a product on C3H, which was presumed to be Mls ^c . Based on strain distributions, this product cannot be encoded by the Mls ^c originally defined by Festenstein. In the present report, three Mls specificities of CBA/H (Mls ^b ) are defined. Based on the strain distribution, we postulate that these specificities are controlled by three loci, three alleles/locus, or by some combination of the preceding two possibilities.     

Effect of Mlsa on antigen presentation to class II-restricted T cells

The nature of the gene products encoded or regulated by the minor lymphocyte-stimulating (Mls) loci remains enigmatic despite extensive experimental evaluation. This work tested the hypothesis that the Mlsa genotype, when compared to the Mlsb genotype, facilitates Ag presentation to class II-restricted T cells. Titrated numbers of H-2-identical, Mls-disparate APC were used to stimulate proliferation of autoreactive, alloreactive, or Ag-specific class II-restricted T cell clones or lines. Apparent preferential presentation by Mlsa vs Mlsb APC obtained from H-2-identical strains was seen infrequently, and when observed, analysis with the use of APC from recombinant inbred lines revealed that preferential presentation did not correlate with the Mls genotype of the APC. These studies show that the Mlsa genotype does not influence overall Ag presentation to class II-restricted T cells.     

T cell responses to Mls determinants are restricted by cross-reactive MHC determinants

The studies presented here investigated the relationship between T cell recognition of MHC-encoded products and non-MHC-linked Mls determinants. The first aspect addressed whether Mls-reactive T cells recognize Mls-encoded products alone or in association with MHC-encoded determinants. Initial studies used Mlsa-specific T cell clones that were generated by repeated stimulation of C57BL/6 or B10.A(5R) spleen cells with DBA/2 lymphoid cells. These clones recognized Mlsa on cells expressing MHC products of the H-2b, H-2d, and H-2k haplotypes, but not the H-2q haplotype. Thus, these cloned T cells were found to recognize Mlsa products in association with public but demonstrably polymorphic H-2 determinants. The question of whether T cell clones that were specific for self-H-2 determinants (autoreactive) or soluble antigen plus syngeneic H-2 (antigen-specific) could also be stimulated by Mlsa determinants was also addressed. A substantial proportion of the antigen-specific or autoreactive T cell clones tested were stimulated by Mlsa determinants. Furthermore, stimulation of these clones by Mlsa was H-2 restricted. The pattern of H-2-restricted recognition of Mlsa by these clones was not distinguishable from that observed in the Mlsa-specific T cell clones, nor was it influenced by the primary specificity or H-2 restriction pattern of a given clone. Although these findings provide a means of explaining the observation that Mls-reactive T cells exist at extremely high precursor frequencies, they also raise questions regarding the nature of the receptor structures which are used by a single T cell in the recognition of two or more apparently distinct stimuli.     

Isoenzymes of aspartate aminotransferase in perennial and annual rye and their hybrids.

Aspartate aminotransferase patterns were screened in a collection of rye genotypes that included 24 accessions of wild perennial rye (Secale montanum Guss.), 6 accessions of cultivated perennial Derzhavin and Tsitsin rye (Secale cereale x S. montanum), 15 accessions of winter and spring rye cultivars (S. cereale L.), and 9 accessions of perennial and annual rye genotypes bred from S. montanum ssp. kuprijanovii, Derzhavin rye, and winter rye for their resistance to fungal diseases. Aspartate aminotransferase is coded for by four loci. The data fit the model where AAT 1/4 is coded by Aat 1 and Aat 4, two duplicate loci, with null and two active alleles for each locus, alleles 1 and 3 for locus Aat 1 and alleles 2 and 4 for locus Aat 4; dimeric AAT 1/4 enzyme molecules are the products of both intralocus and interloci complementation. Allele 1 of Aat 1 was the most prominent in the isoenzyme patterns of the rye species. Alleles null and 2 of Aat 4 were twice as frequent in the perennial rye accessions, including Derzhavin and Tsitsin rye, than in winter and spring rye. In contrast, allele 4 of Aat 4 was characteristic of S. cereale. Within the screened collection, locus Aat 2 was monomorphic. Among three alleles of Aat 3, allele 2 dominated isoenzyme profiles of both rye species, whereas the other two alleles were species-specific: allele 1 was characteristic of S. montanum and allele 3 was found only in S. cereale. Key words : rye, Secale cereale, Secale derzhavinii, Secale montanum, aspartate aminotransferase, isoenzymes, perennial habit, polymorphism.     

The genetics of the sixth and seventh components of complement in the dog: Polymorphism,linkage, locus duplication,and silent alleles

The complement components C6 and C7 exhibit genetic polymorphism in the domestic dog. In the case of C6, there is a single locus with a null allele and two structural alleles; in the case of C7, there are two linked loci, each with three structural alleles. There is a null allele or locus deletion at one of these loci. In all cases, inheritance is autosomal and codominant. The C7 loci are closely linked to each other and to C6. This complex is not close to the dog major histocompatibility complex (MHC) locus.     

Specific neonatally induced tolerance to Mls locus determinants

Neonatal injection of CBA/HT6T6 (H-2k, Mlsb) mice with adult, Mls-incompatible (CBA/J [H-2k, Mlsd] X CBA/HT6T6)F1 spleen cells results in the abrogation of cell proliferation and interleukin 2 (IL 2) production in bulk mixed lymphocyte cultures, when spleen cells from the inoculated mice are tested at 6 to 8 wk of age with stimulator cells expressing the Mlsd of the tolerizing inoculum. In limiting dilution assays, this tolerant state was manifested in a 25- to 550-fold (280-fold average) decrease in the frequency of precursors of Mlsd-responsive IL 2-producing T cells. Tolerance was specific in that the frequencies of precursors of IL 2-producing cells responding to Con A, allogeneic H-2d, and self-Ia were not affected. The observed low frequency of Mls-responsive cells was due neither to extensive chimerism resulting in the dilution of Mlsd-responsive cells by the nonresponsive F1 cells of the inoculum, nor to the action of suppressor cells. These findings indicate that neonatal injection of Mls-incompatible spleen cells produces a state of specific tolerance by a clonal deletion or inactivation mechanism. This specific tolerance supports the view that 1) the Mls locus encodes or regulates the expression of defined alloantigenic determinants and 2) Mls-incompatible responder mice have specific receptors for Mls determinants on clonally distributed IL 2-producing responder T cells.     

Expressed hypervariable polymorphism of apolipoprotein (a)

Elevated plasma lipoprotein (a) (LP(a] levels are an independent predictor of the development of premature atherosclerosis in humans. The LP(a) particle consists of two disulfide-linked proteins, apolipoprotein (APO) B and APO(a). The APO(a) is a highly glycosylated protein which carries the LP(a) antigen. Genetic polymorphism in the APO(a) molecule has been reported, and, depending on the sensitivity of the method used, 6-11 alleles at the APO(a) structural locus have been documented in the literature. In this investigation, we have used a high-resolution SDS-agarose electrophoresis method followed by immunoblotting to screen APO(a) polymorphism in 54 families with 130 offspring. This method identified a total of 23 different APO(a) isoforms, and their genetic basis was confirmed in families. In addition to the detectable products of 23 APO(a) alleles, the family data predict the existence of a "null" allele. Of the total 270 individuals tested, 209 (77.4%) revealed double-banded phenotypes and 61 (22.6%) revealed single-banded phenotypes. In the unrelated sample of 140 individuals, however, 114 (81.4%) and 26 (18.6%) had double- and single-banded phenotypes, respectively. When the segregation pattern of single-banded phenotypes in the unrelated sample was followed in families, only nine (6.4%) were found to be true homozygotes, and the remaining 17 (12.2%) were classified as heterozygotes for the null allele. Of the 276 possible phenotypes predicted for 23 alleles in a large population, we observed 115 (42%) phenotypes in our restricted sample. On the basis of our results from the family data, we hypothesize the existence of at least 24 alleles, including a null allele, at the APO(a) structural locus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immune responses in vitro

The Mls locus was originally defined to have four alleles; three controlled products that were detectable in primary mixed leukocyte reactions (MLR), whereas one, b, was described as being null. Recently, other investigators postulated that the Mls locus is nonpolymorphic, being composed of the b null allele and of a singly expressed allele previously thought to be the a and d alleles. We previously reported that products controlled by Mls ^aand Mls ^dwere antigenically distinct and therefore are not controlled by the same allele, and the product of Mls ^bon cells of three different strains was easily detectable by Mls ^aand Mls ^dresponding cells. Thus the b allele is not null. In the present report evidence is presented which indicates that both Mls ^band Mls ^cencoded products were undetectable by MLR when in the presence of Mls ^aor Mls ^d. This was demonstrated by (a) the inability of Mls ^a/Mls ^cand Mls ^a/Mls ^bF₁ cells to stimulate Mls ^aresponding cells and Mls ^d/Mls ^cand Mls ^d/Mls ^bcells to stimulate Mls ^dcells; (b) the positive response of Mls ^a/Mls ^band Mls ^d/Mls ^bF₁-hybrid cells to Mls ^b-encoded products; and (c) the reactivity of Mls ^a/Mls ^cand Mls ^d/Mls ^cF₁ hybrid cells to Mls ^c-encoded determinants.     

Estimating Relatedness in the Presence of Null Alleles

Studies of genetics and ecology often require estimates of relatedness coefficients based on genetic marker data. However, with the presence of null alleles, an observed genotype can represent one of several possible true genotypes. This results in biased estimates of relatedness. As the numbers of marker loci are often limited, loci with null alleles cannot be abandoned without substantial loss of statistical power. Here, we show how loci with null alleles can be incorporated into six estimators of relatedness (two novel). We evaluate the performance of various estimators before and after correction for null alleles. If the frequency of a null allele is <0.1, some estimators can be used directly without adjustment; if it is >0.5, the potency of estimation is too low and such a locus should be excluded. We make available a software package entitled PolyRelatedness v1.6, which enables researchers to optimize these estimators to best fit a particular data set.