Binding of human milk to pathogen receptor DC-SIGN varies with bile salt-stimulated lipase (BSSL) gene polymorphism

Objective

Dendritic cells bind an array of antigens and DC-SIGN has been postulated to act as a receptor for mucosal pathogen transmission. Bile salt-stimulated lipase (BSSL) from human milk potently binds DC-SIGN and blocks DC-SIGN mediated trans-infection of CD4⁺ T-lymphocytes with HIV-1. Objective was to study variation in DC-SIGN binding properties and the relation between DC-SIGN binding capacity of milk and BSSL gene polymorphisms.

Study Design

ELISA and PCR were used to study DC-SIGN binding properties and BSSL exon 11 size variation for human milk derived from 269 different mothers distributed over 4 geographical regions.

Results

DC-SIGN binding properties were highly variable for milks derived from different mothers and between samplings from different geographical regions. Differences in DC-SIGN binding were correlated with a genetic polymorphism in BSSL which is related to the number of 11 amino acid repeats at the C-terminus of the protein.

Conclusion

The observed variation in DC-SIGN binding properties among milk samples may have implications for the risk of mucosal transmission of pathogens during breastfeeding.     

Recombinant human bile salt-stimulated lipase: an example of defectiveO-glycosylation of a protein produced in milk of transgenic mice

The expression of recombinant human bile salt-stimulated lipase (bssl) was targeted to the lactating mammary gland of transgenic mice. Expression of recombinant genes comprisingbssl cDNA, or alternatively genomicbssl DNA, under control of regulatory elements derived from the murine whey acidic protein (wap) gene was achieved and evaluated. Constructs containing genomicbssl sequences mediated high levels (0.5–1, mg ml^–1) of recombinant human BSSL in the milk. The recombinant BSSL produced was purified, biochemically characterized and compared to native BSSL and recombinant BSSL produced in mouse C127 and hamster CHO cells. Recombinant BSSL derived from transgenic mice showed a different migration and distribution after SDS-PAGE electrophoresis, lower apparent molecular mass on size-exclusion chromatography and no detectable interactions with a panel of lectins. These results indicate a significantly lower degree ofO-glycosylation of recombinant BSSL in milk from transgenic mice than was found for the native enzyme or recombinant CHO- or C127 cell-produced BSSL. Despite these differences, mouse-milk-derived recombinant BSSL exhibited similar lipase activity, the same, stability to low pH and similar sensitivity to elevated temperatures as the native enzyme. The observation that mouse-C127-cell-produced recombinant BSSL is heavilyO-glycosylated makes species-related restrictions less attractive as an explanation for the reducedO-glycosylation.     

DNA length polymorphism located 5'' to the human myelin basic protein gene.

A region of DNA 5' to the human myelin basic protein (MBP) gene, located on the long arm of chromosome 18, is a site of restriction-fragment-length polymorphism (RFLP) showing 37% heterozygosity in 40 subjects studied. Southern transfer analysis using a 0.9-kb genomic fragment encompassing the first exon of the human MBP gene reveals this polymorphism with at least nine restriction enzymes, indicating that insertion, deletion, or both is the basis for the DNA length variation. Double restriction-enzyme digest analysis suggests that this polymorphism is within the region 0.5-2.0 kb upstream of the coding region of the first exon of the human MBP gene. Eleven different allelic RFLPs were identified, differing in size by as many as 450 bp. The distribution of insertion/deletion-size variants from this region is bimodal, with most restriction fragments varying in size over a 0.1-kb range. Pedigree analysis of polymorphism at this site in one three-generation family shows Mendelian assortment of parental haplotypes. The form and frequency of polymorphism generated by this site is similar to that reported for human DNA regions comprised of homologous short tandem repeats.     

矛尾鱼Hoxa—11基因克隆及5′端序列分析

Hoxa-11基因调节鱼类鳍和四足动物肢的发育,在脊椎动物进化过程中起着重要的作用,利用人和鼠的Hoxa-11基因保守序列设计了两个兼并引物,通过PCR扩增到了矛尾鱼的Hoxa-11基因,经克隆和DNA序列分析,该片段为2065bp,包括绝大部分外显子Ⅰ,内含子和部分外显子Ⅱ,编码204个氨基酸,其氨基酸序列与人、鼠、鸡、蛙和斑马鱼的同源性分别为66.0%、67.6%、74.4%、72.8%和59.7%。外显子Ⅰ的长度从矛尾鱼到蛙、鸡、鼠和人呈现逐步上升趋势,人比矛尾鱼增长了16%,进一步分析,外显子Ⅰ可分为4个区域;两个高度保守区域,1个中度保守区域和1个可变区域,外显子Ⅰ的长度变化主要是由于可变区域内丙氨酸同聚物以及两侧富含甘氨酸和丝氨酸序列的累积。矛尾鱼只有1个由两个丙氨酸组成的同类物,蛙有1个由5个连续丙氨酸组成的同聚物,而鸡、鼠和人有3个丙氨酸同聚物,其中最大的同聚物由7个连续丙氨酸组成,而且在同聚物两侧出现了富含甘氨酸和丝氨酸序列。这表明可变区域可能与脊椎动物进化和鳍-肢转换过程中新功能的获得有关。同源异型盒所在的外显子Ⅱ区和剪接位点是高度保守的。内含子的长度变化较大,但在其内部也发现了两个高度保守的35bp和16bp的DNA片段,这两个片段在人、鼠、鸡、蛙和矛尾鱼中是完全相同的,这些序列的高度保守性提示其功能上的重要性。     

HIV-1 disease progression is associated with bile-salt stimulated lipase (BSSL) gene polymorphism

Background

DC-SIGN expressed by dendritic cells captures HIV-1 resulting in trans-infection of CD4⁺ T-lymphocytes. However, BSSL (bile-salt stimulated lipase) binding to DC-SIGN interferes with HIV-1 capture. DC-SIGN binding properties of BSSL associate with the polymorphic repeated motif of BSSL exon 11. Furthermore, BSSL binds to HIV-1 co-receptor CXCR4. We hypothesized that BSSL modulates HIV-1 disease progression and emergence of CXCR4 using HIV-1 (X4) variants.

Results

The relation between BSSL genotype and HIV-1 disease progression and emergence of X4 variants was studied using Kaplan Meier and multivariate Cox proportional hazard analysis in a cohort of HIV-1 infected men having sex with men (n = 334, with n = 130 seroconverters). We analyzed the association of BSSL genotype with set-point viral load and CD4 cell count, both pre-infection and post-infection at viral set-point. The number of repeats in BSSL exon 11 were highly variable ranging from 10 to 18 in seropositive individuals and from 5–17 in HRSN with 16 repeats being dominant (>80% carry at least one allele with 16 repeats). We defined 16 to 18 repeats as high (H) and less than 16 repeats as low (L) repeat numbers. Homozygosity for the high (H) repeat number BSSL genotype (HH) correlated with high CD4 cell numbers prior to infection (p = 0.007). In HIV-1 patients, delayed disease progression was linked to the HH BSSL genotype (RH = 0.462 CI = 0.282–0.757, p = 0.002) as was delayed emergence of X4 variants (RH = 0.525, 95% CI = 0.290–0.953, p = 0.034). The LH BSSL genotype, previously found to be associated with enhanced DC-SIGN binding of human milk, was identified to correlate with accelerated disease progression in our cohort of HIV-1 infected MSM (RH = 0.517, 95% CI = 0.328–0.818, p = 0.005).

Conclusion

We identify BSSL as a marker for HIV-1 disease progression and emergence of X4 variants. Additionally, we identified a relation between BSSL genotype and CD4 cell counts prior to infection.     

Polymorphism of exon 4 in the CANP-3 gene in patients with primary myopathies

The structures of the gene for calpain (CANP-3) and of the DMD gene were analyzed in patients with primary myopathies [limb-girdle muscular distrophy (LGMD) and Duchenne-Becker myodystrophy (DBM)] from various regions of Russia. Via amplification of DNA isolated from the peripheral blood lymphocytes of 74 patients, extended deletions were found in 18 out of 55 patients with DBM. In none of the 19 patients with LGMD, were extended deletions in the CANP-3 gene found. In most patients with LGMD, the amplification of the promoter region and exons 1, 2, 3, 4, 5, and 6 of the CANP-3 gene yielded a single product of corresponding length, but in six patients (three sib pairs), amplification of exon 4 of the CANP-3 gene yielded two products of different size. The following single-strand conformation polymorphism (SSCP) analysis revealed a pronounced polymorphism of exon 4 of the CANP-3 gene in 14 out of 19 patients with LGMD. This structure of exon 4 of the CANP-3 gene was found neither in 16 patients with DBM who had deletions in the DMD gene nor in 16 patients with DBM who had no deletions in the DMD gene.     

Recombinational biases in the rearranged C1-inhibitor genes of hereditary angioedema patients

DNA structural changes responsible for hereditary angioedema were sought in the C1-inhibitor gene, which contains unusually dense clusters of Alu repeats in various orientations. Among patients belonging to 45 unrelated families, eight partial C1-inhibitor gene deletions and a partial duplication were found. Four deletions had one of the boundaries within the gene and the other in extragenic regions--in three cases 5' of the gene and in one case 3' of the gene. The boundaries of the partial duplication and of the remaining four deletions mapped instead within a few kilobases of exon 4. The same element--Alu 1--the first of three tandem Alu repeats preceding exon 4, contained one of the breakpoints of each of these five rearrangements. Moreover, these recombination breakpoints spread over the entire length of Alu 1, in contrast with the tight clustering observed near the 5' end of Alu sequences rearranged in other human genes. Thus, two uncommon recombinational biases are observed in the Alu rearrangements of hereditary angioedema patients; one promotes the occurrence of intragenic breakpoints in a single Alu repeat, and the other allows the breaks to be distributed over the entire Alu structure rather than within the hot spot of the left Alu monomer. A region of potential Z-DNA structure, located 1.7 kb upstream of Alu 1, may contribute to both peculiarities.     

Changes in glycosylation of human bile-salt-stimulated lipase during lactation

Bile-salt-stimulated lipase (BSSL) is an enzyme in human milk, which is important for the fat digestion in the newborn infant. BSSL is highly glycosylated and includes one site for N-glycosylation and several sites for O-glycosylation. BSSL has previously been found to express Lewis a, Lewis b, and Lewis x carbohydrate antigens. In this study, glycosylation of BSSL was studied at different times during lactation. BSSL was purified from milk collected individually from four donors at several different times during the first 6 months of lactation. The BSSL glycans were characterized through monosaccharide analysis, high-pH anion-exchange chromatography, matrix-assisted laser desorption-ionization mass spectrometry, and ELISA. Both total carbohydrate content and relative amount of sialic acid were higher in BSSL from the first lactation month as compared to BSSL from milk collected later in lactation. BSSL from the first lactation month also showed a different composition of sialylated O-linked glycans and the N-linked oligosaccharides consisted of lower amounts of fucosylated structures compared to later in lactation. We also found a gradual increase in the expression of the carbohydrate epitope Lewis x on BSSL throughout the lactation period. This study shows that glycosylation of BSSL is dependent on blood group phenotype of the donor and changes substantially during the lactation period.     

Molecular cloning of two novel mucin-like genes in the disease-susceptibility locus for diffuse panbronchiolitis

Diffuse panbronchiolitis (DPB) is a rare complex genetic disease affecting East Asians and is strongly associated with the class I human leukocyte antigens (HLA)-B54 in Japanese and HLA-A11 in Koreans. We recently showed that an HLA-associated major susceptibility gene for DPB is probably located within the 200?kb in the class I region 300?kb telomeric of the HLA-B locus on the chromosome 6p21.3. We cloned two novel mucin-like genes designated panbronchiolitis related mucin-like 1 and 2 (PBMUCL1 and PBMUCL2) in the candidate region, which form a mucin-like gene cluster together with two adjacent genes, MUC21 and DPCR1. PBMUCL1 gene expression was remarkably upregulated by polyinosine-polycytidylic acid [poly(I:C)] stimulation in normal human bronchial epithelial cells redifferentiated at the air-liquid interface. We found genetic polymorphisms in PBMUCL1 gene which were associated with DPB: the A-allele of the PBMUCL1 intron 2 single nucleotide polymorphism (SNP) was positively associated and variable numbers of tandem repeats (VNTR) polymorphism in exon 3 (1,890-base pair deletion) was negatively associated. Despite a strong association with HLA-B in the Japanese, the mucin-like gene PBMUCL1 is also one of the candidate genes of DPB susceptibility.     

Characterization of a highly polymorphic region 5′ to JH in the human immunoglobulin heavy chain

A cloned DNA segment 1.25 kilobases (kb) upstream from the joining segments of the human heavy chain immunoglobulin gene revealed extensive polymorphic variation at this locus, and the polymorphic pattern was stably transmitted to the next generation. Genomic restriction analysis showed that the polymorphism was caused by insertions/deletions within an MspI/BamHI fragment. Sequencing of one allele, 848 base pairs (bp) long, revealed eleven 50-base-pair tandem repeats. A second allele, 648 bp long, was cloned from a human genomic cosmid library, sequenced, and found to contain four fewer repeats than the first allele. A survey of 186 chromosomes from unrelated individuals of primarily northern European descent revealed at least six alleles.     

WT1 exon 1 deletion/insertion mutations in Wilms tumor patients, associated with di- and trinucleotide repeats and deletion hotspot consensus sequences.

The WT1 gene is known to play a role in at least some cases of Wilms tumor (WT). The first exon of the gene is highly GC rich and contains many short tandem di- and trinucleotide repeats, interrupted direct repeats, and CCTG (CAGG) motifs that have been identified as hotspots for DNA deletions. We have analyzed 80 WT patient samples for mutations in the first exon of WT1, either by SSCP analysis of the first 131 bp of the coding portion of WT1 exon 1 or by size analysis of a PCR product encompassing the coding region of exon 1 in addition to flanking noncoding regions. We report here the occurrence of somatic and germ-line deletion and insertion mutations in this portion of the gene in four WT patients. The mutations are flanked by short direct repeats, and the breakpoints are within 5 nt of a CCTG (CAGG) sequence. These data suggest that a distinctive mutational mechanism, previously unrecognized for this gene, is important for the generation of DNA mutations at the WT1 locus.     

Prenatal prediction of androgen insensitivity syndrome using exon 1 polymorphism of the androgen receptor gene.

Exon 1 polymorphism of the androgen receptor (AR) gene is characterized by a (CAG)n(CAA) repeat at position 172 following the translation start codon. The aim of this study was to determine whether AR gene exon 1 polymorphism could be used to perform prenatal diagnosis in high risk families with complete or partial androgen insensitivity syndrome. After enzymatic amplification of a 1 kilobase exon 1 fragment, each DNA was simultaneously digested by MspI and PstI restriction enzymes. After electrophoresis on a 15% electrophoresis on a 15% acrylamide gel or a 6% Nusieve gel, we measured the size of the obtained fragments and determined the number of CAG repeats since a 282 basepair fragment corresponds to 21 CAG. We previously showed that the number of CAG repeats within the AR gene exon 1 in 23 families with complete or partial androgen insensitivity syndrome was 19 +/- 4. By this method, we detected heterozygosity in 50% of the mothers. We present here 2 exclusion prenatal diagnoses using exon 1 polymorphism of the AR gene. Family A presented a boy with a severe form of partial androgen insensitivity syndrome. The mother had 2 uncles with ambiguous genitalia. In family B, the affected child had a complete androgen insensitivity syndrome. In both families, analysis of the AR gene exon 1 polymorphism of the trophoblastic DNA showed the presence of the normal maternal X chromosome. The parents decided to carry on the gestation. In family A, the newborn had normal male external genitalia. In family B, sonography confirmed the presence of normal male external genitalia. These data suggest that exon 1 polymorphism of the AR gene could be prenatally used to predict androgen insensitivity syndrome.     

Phylogenetic analysis of DNA length mutations in a repetitive region of the Hawaiiandrosophila yolk protein geneYp2

Nucleotide sequence analysis has demonstrated that interspecific size variation in the YP2 yolk protein among HawaiianDrosophila is due to in-frame insertions and deletions in two repetitive segments of the coding region of the Yp2 gene. Sequence comparisons of the complex repetitive region close to the 5′ end of this gene across 34 endemic Hawaiian taxa revealed five length morphs, spanning a length difference of 21 nucleotides (nt). A phylogenetic character reconstruction of the length mutations on an independently derived molecular phylogeny showed clade-specific length variants arising from six ancient events: two identical insertions of 6 nt, and four deletions, one of 6 nt, one of 12 nt, and two identical but independent deletions of 15 nt. These mutations can be attributed to replication slippage with nontandem trinucleotide repeats playing a major role in the slipped-strand mispairing. Geographic analysis suggests that the 15 nt deletion which distinguishes theplanitibia subgroup from thecyrtoloma subgroup occurred on Oahu about 3 million years ago. The homoplasies observed caution against relying too heavily on nucleotide insertions/deletions for phylogenetic inference. In contrast to the extensive repeat polymorphisms within otherDrosophila and the human species, the more complex 5′Yp2 repetitive region analyzed here appears to lack polymorphism among HawaiianDrosophila, perhaps due to founder effects, low population sizes, and hitchhiking effects of selection on the immediately adjacent 5′ region. Correspondence to: M.P. Kambysellis     

The human factor VII gene is polymorphic due to variation in repeat copy number in a minisatellite

The gene coding for human factor VII, a vitamin K-dependent coagulation factor, contains five minisatellite imperfect tandem repeats with monomer element lengths ranging from 14 to 37 bp, and copy numbers ranging from 6 to 52. Three of these repeats are entirely within introns, one is entirely in an untranslated portion of an exon, and one spans an exon-intron border and contains coding sequence. A consensus sequence derived from a comparison of the monomers is similar to a core sequence found in other minisatellites. All of the minisatellites display higher-order periodicities. At least one of these minisatellites is polymorphic. A variation in repeat copy number has been observed in a tandem-repeat region in the seventh factor-VII intron.     

Structural characterization of the N-linked oligosaccharides in bile salt-stimulated lipase originated from human breast milk

The detailed structures of N- glycans derived from bile salt-stimulated lipase (BSSL) found in human milk were determined by combining exoglycosidase digestion with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. The N- glycan structures were conclusively determined in terms of complexity and degree of fucosylation. Ion-exchange chromatography with pulsed amperometric detection, together with mass-spectral analysis of the esterified N- glycans, indicated the presence of monosialylated structures. The molecular mass profile of esterified N- glycans present in BSSL further permitted the more detailed studies through collision-induced dissociation (CID) and sequential exoglycosidase cleavages. The N- glycan structures were elucidated to be complex/dibranched, fucosylated/complex/dibranched, monosialylated/complex/dibranched, and monosialylated/fucosylated/dibranched entities.     

Evolution of exon 1 of the dopamine D4 receptor (DRD4) gene in primates

The dopamine D4 receptor (DRD4) gene exhibits a large amount of expressed polymorphism in humans. To understand the evolutionary history of the first exon of DRD4-which in humans contains a polymorphic 12bp tandem duplication, a polymorphic 13bp deletion, and other rare variants-we examined the homologous exon in thirteen other primate species. The great apes possess a variable number of tandem repeats in the same region as humans, both within and among species. In this sense, the 12bp tandem repeat of exon 1 is similar to the 48bp VNTR of exon 3 of DRD4, previously shown to be polymorphic in all primate species examined. The Old World monkeys show no variation in length, and a much higher conservation of amino acid sequence than great apes and humans. The New World monkeys show interspecific differences in length in the region of the 12bp polymorphism, but otherwise show the higher conservation seen in Old World monkeys. The different patterns of variation in monkeys compared to apes suggest strong purifying selective pressure on the exon in these monkeys, and somewhat different selection, possibly relaxed selection, in the apes.     

Production of recombinant human bile salt-stimulated lipase in Pichia pastoris.

Recombinant human bile salt-stimulated lipase (rhBSSL) was efficiently expressed under the control of the AOX1 gene promoter in Pichia pastoris. Human BSSL has 16 successively repeated sequences in the carboxy terminal region. The sequence consists of 11 amino acid residues. The coding sequence for the middle 11 of the 16 repeats was removed from hBSSL cDNA to facilitate efficient secretory expression. The clone used for fermentation was a transformant of GS115 (his4) integrated with four copies of the expression cassette containing the modified hBSSL cDNA. Unique fermentation conditions were required for efficient expressions of rhBSSL in the high cell-density fermentation. A sufficient glycerol feed at 30 degrees C and pH 4 under an adequate concentration of dissolved oxygen in the growth phase make the cells active over a long induction period of approximately 15 days. On methanol induction, the concentration of dissolved oxygen should be maintained very low in the presence of sorbitol and skimmed milk at 20 degrees C and pH 5.7. Under these conditions, 0.8-1 g of rhBSSL was secreted in 1 liter of the medium. By immunoelectron microscopy, rhBSSL-tagged gold particles were located in secretion microbodies after the beginning of methanol induction. The secreted rhBSSL was efficiently captured and purified by expanded bed adsorption chromatography.     

Smallest region of overlap in Wilms tumor deletions uniquely implicates an 11p13 zinc finger gene as the disease locus.

The development of Wilms tumor (WT) has been associated with the inactivation of a "tumor suppressor" locus in human chromosome 11 band p13. Several WTs that exhibit homozygous deletions of an 11p13 candidate WT gene in its entirety have been reported. We report here a partial deletion of the candidate gene which, upon comparison with other documented homozygous deletions, permitted a precise definition of the critical genomic target in Wilms tumor. The smallest region of overlap between these deletions is a 16-kb segment of DNA encompassing the 5' exon(s) of an 11p13 gene coding for a zinc finger protein, together with an associated CpG island. This finding supports the notion that the candidate gene in question corresponds to the 11p13 WT1 Wilms tumor locus.     

Mechanisms of divergence and convergence of the human immunoglobulin alpha 1 and alpha 2 constant region gene sequences

Nucleotide sequences of the human alpha 1 and two allelic alpha 2 immunoglobulin heavy chain constant region genes are presented. The genes contain three exons, each encoding a single constant region protein domain. The protein hinge region is encoded at the 5' end of the second exon, and the rapid evolutionary changes in length of the hinge correspond to duplications or deletions within the hinge-coding region, probably facilitated by repeats in the DNA sequence. Alignment of the alpha 1 and alpha 2 gene sequences reveals an unusual coupled deletion-duplication in the 5'-flanking region, which can be explained in terms of a slipped-strand mispairing model. Comparison of nucleotide sequences of the alpha 1 gene and two alleles of the alpha 2 gene indicates a localized transfer of genetic information from the 3' end of the alpha 1 gene to one of the alpha 2 alleles, probably by a gene conversion. At one end of the region within which conversion apparently occurred, there is a 40 bp sequence of the type that can form Z-DNA.     

Dynamic mutations in human genes: A review of trinucleotide repeat diseases

Dynamic mutations in human genes result from unstable trinucleotide repeats embedded within the transcribed region. The changeable nature of these mutations from generation to generation is in contrast to the static inheritance of other single-gene mutational events, e.g. point mutations, deletions, insertions and inversions, typically associated with Mendelian inheritance patterns. Intergenerational instability of dynamic mutations within families has provided an explanation for the genetic anticipation, leading to increasing severity or earlier age of onset in successive generations, associated with certain inherited disorders. While models for genomic instability presume that trinucleotide repeat expansion results from disruption of the DNA replication process, experimental evidence has not yet been obtained in support of this contention. Nevertheless, examples of unstable trinucleotide repeats continue to increase, although not all are associated with a specific phenotype. Five disorders resulting from small-scale expansions of CAG repeats within the protein-coding region are known: spinobulbar muscular atrophy, Huntington’s disease, spinocerebellar ataxia type 1, dentatorubral-pallidoluysian atrophy (DRPLA) and Machado-Joseph disease. A sixth disorder, Haw River syndrome, is allelic to DRPLA. Five folate-sensitive chromosomal fragile sites characterized to date, viz. FRAXA, FRAXE, FRAXF, FRA11B and FRA16A, all have large-scale CGG repeat expansion. Two disorders, fragile X syndrome and FRAXE mental retardation, result from instability of CGG repeats in the 5’ untranslated region ofFMR1 andF M R2 genes respectively. FRA11B lies close to chromosome 1 1q deletion endpoints in many Jacobsen syndrome patients and may be related to the deletion event producing partial aneuploidy for 1lq. Expansion of FRAXF and FRA16A has not been associated with a phenotype. Myotonic dystrophy results from a large-scale CTG expansion in the 3’ untranslated region of the myotonin protein kinase gene while Friedreich’s ataxia has recently been found to have a large-scale GAA repeat in the first intron ofX25. This article reviews the characteristics of trinucleotide repeat disorders and summarizes current understanding of the molecular pathophysiology.