Polypurine tract formation by Ty1 RNase H.

To better understand the mechanism by which Ty1 RNase H creates the polypurine tract (PPT) primer, we have demonstrated the polymerase-dependent hydrolytic activity of Ty1 reverse transcriptase (RT) during minus-strand synthesis. Using RNase H and polymerase mutants of the recombinant Ty1 RT protein, we show that the two domains of Ty1 RT can act independently of one another. Our results indicate that RNA/DNA substrates containing a short RNA PPT, which serve as primers for plus-strand DNA synthesis, are relatively resistant to RNase H cleavage. RNA substrates with a correct 5' end but with 3' end extending beyond the plus-strand initiation site were cleaved specifically to generate the correct 3' end of the PPT. Using long RNA/DNA duplexes containing the PPT, we show that Ty1 RT is able to make specific internal cleavages that could generate the plus-strand primer with correct 5' and 3' ends. Long RNA/DNA duplexes with mutations in the PPT or in a U-rich region upstream of the PPT, which abolish plus-strand initiation in vivo, were not cleaved specifically at the 5' end of the PPT. Our work demonstrates that the in vitro enzyme can recapitulate key processes that control proper replication in vivo.

Rab27a is required for regulated secretion in cytotoxic T lymphocytes.

Rab27a activity is affected in several mouse models of human disease including Griscelli (ashen mice) and Hermansky-Pudlak (gunmetal mice) syndromes. A loss of function mutation occurs in the Rab27a gene in ashen (ash), whereas in gunmetal (gm) Rab27a dysfunction is secondary to a mutation in the alpha subunit of Rab geranylgeranyl transferase, an enzyme required for prenylation and activation of Rabs. We show here that Rab27a is normally expressed in cytotoxic T lymphocytes (CTLs), but absent in ashen homozygotes (ash/ash). Cytotoxicity and secretion assays show that ash/ash CTLs are unable to kill target cells or to secrete granzyme A and hexosaminidase. By immunofluorescence and electron microscopy, we show polarization but no membrane docking of ash/ash lytic granules at the immunological synapse. In gunmetal CTLs, we show underprenylation and redistribution of Rab27a to the cytosol, implying reduced activity. Gunmetal CTLs show a reduced ability to kill target cells but retain the ability to secrete hexosaminidase and granzyme A. However, only some of the granules polarize to the immunological synapse, and many remain dispersed around the periphery of the CTLs. These results demonstrate that Rab27a is required in a final secretory step and that other Rab proteins also affected in gunmetal are likely to be involved in polarization of the granules to the immunological synapse.

Rab geranylgeranyl transferase alpha mutation in the gunmetal mouse reduces Rab prenylation and platelet synthesis.

Few molecular events important to platelet biogenesis have been identified. Mice homozygous for the spontaneous, recessive mutation gunmetal (gm) have prolonged bleeding, thrombocytopenia, and reduced platelet alpha- and delta-granule contents. Here we show by positional cloning that gm results from a G-->A substitution mutation in a splice acceptor site within the alpha-subunit of Rab geranylgeranyl transferase (Rabggta), an enzyme that attaches geranylgeranyl groups to Rab proteins. Most Rabggta mRNAs from gm tissues skipped exon 1 and lacked a start codon. Rabggta protein and Rab geranylgeranyl transferase (GGTase) activity were reduced 4-fold in gm platelets. Geranylgeranylation and membrane association of Rab27, a Rab GGTase substrate, were significantly decreased in gm platelets. These findings indicate that geranylgeranylation of Rab GTPases is critical for hemostasis. Rab GGTase inhibition may represent a new treatment for thrombocytosis and clotting disorders.

Fidelity of retrotransposon replication.

Ty1, the genetically tractable retrotransposable element found in the yeast Saccharomyces cerevisiae, closely resembles vertebrate retroviruses both in structure and in mechanism of replication. By direct sequence analysis, we examined the rate and spectrum of new mutations appearing during a single cycle of Ty1 replication. The rate of new mutations was comparable to those seen for replicating retroviruses. All observed changes were base substitutions, and their location suggested that template ends may be hot spots for generating these mutations. To test this, we developed methods to examine, at the nucleotide level, the end structure of the expected Ty1 replication intermediates. Our results demonstrate that Ty1 reverse transcriptase can add terminal non-templated bases in vivo during each step in replication. Furthermore, Ty1 RNAse H creates multiple template ends by imprecisely cleaving RNA. This expands the range of sites of subsequent non-templated base addition. Finally, on reaching template ends, Ty1 reverse transcriptase can strand transfer to inappropriate templates. Taken together, these mutagenic mechanisms may influence the evolution of particular regions of the Ty1 genome and serve as a mechanism to regulate the overall level of Ty1 transposition in its host cell.

In vivo Ty1 reverse transcription can generate replication intermediates with untidy ends.

Ty1 retrotransposition, like retroviral replication, is a complex series of events requiring reverse transcription of an RNA intermediate, RNA-primed minus- and plus-strand DNA synthesis, multiple strand transfers, and precise cleavages of the template and primers by RNase H. In this report, we examine the structure of in vivo Ty1 replication intermediates, specifically with regard to the behavior of reverse transcriptase upon reaching template ends and to the precision with which RNase H might generate these ends. While the expected 3' termini were always identified, terminal nontemplated bases were also observed at all of the RNA and DNA template ends examined. Nontemplated A residues were most common at all 3' ends, although C residues were preferentially added to minus-strand termini paused at the 5' end of capped Ty1 RNA. In addition, we observed that RNase H removal of the tRNA primer and of the polypurine tract was not always precise or efficient. Finally, we noted numerous instances of Ty1 reverse transcriptase transferring from normal Ty1 template ends to various tRNA templates, with continued synthesis to specific modified bases. A similar pattern was obtained for Ty2, indicating that template ends offer unique opportunities for these two related reverse transcriptases to generate errors.

Replication errors during in vivo Ty1 transposition are linked to heterogeneous RNase H cleavage sites.

We previously identified a mutational hotspot upstream of the Ty1 U5-primer binding site (PBS) border and proposed a novel mechanism to account for this phenomenon during Ty1 replication. In this report, we verify key points of our model and show that in vivo RNase H cleavage of Ty1 RNA during minus-strand strong-stop synthesis creates heterogeneous 5' RNA ends. The preferred cleavage sites closest to the PBS are 6 and 3 bases upstream of the U5-PBS border. Minus-strand cDNA synthesis terminates at multiple sites determined by RNase H cleavage, and DNA intermediates frequently contain 3'-terminal sequence changes at or near their template ends. These data indicate that nontemplated terminal base addition during reverse transcription is a real in vivo phenomenon and suggest that this mechanism is a major source of sequence variability among retrotransposed genetic elements.

Replication infidelity during a single cycle of Ty1 retrotransposition.

Retroviruses undergo a high frequency of genetic alterations during the process of copying their RNA genomes. However, little is known about the replication fidelity of other elements that transpose via reverse transcription of an RNA intermediate. The complete sequence of 29 independently integrated copies of the yeast retrotransposon Ty1 (173,043 nt) was determined, and the mutation rate during a single cycle of replication was calculated. The observed base substitution rate of 2.5 x 10(-5) bp per replication cycle suggests that this intracellular element can mutate as rapidly as retroviruses. The pattern and distribution of errors in the Ty1 genome is nonrandom and provides clues to potential in vivo molecular mechanisms of reverse transcriptase-mediated error generation, including heterogeneous RNase H cleavage of Ty1 RNA, addition of terminal nontemplated bases, and transient dislocation and realignment of primer-templates. Overall, analysis of errors generated during Ty1 replication underscores the utility of a genetically tractable model system for the study of reverse transcriptase fidelity.

Impact of premature stop codons on mRNA levels in infantile Sandhoff disease.

Sandhoff disease is an autosomal recessive lysosomal storage disease resulting from mutations of the HEXB gene encoding the beta subunit of beta-hexosaminidase A. Fibroblast lines from four patients with the infantile form of the disease were investigated for mutations by single strand conformation polymorphism analysis and direct sequencing of PCR products. Two of the cell lines were homozygous for a common, 16 kb deletion of the 5' end of HEXB gene. The two other cell lines contained the 16 kb deletion along with a second mutant allele generating a stop codon: in one case a nonsense mutation, C850-->T, which generated a stop codon at codon 284; and in the other, a single base deletion, delta T1344, which generated a stop codon at codon 451. One additional cell line investigated was a compound heterozygote for two frameshift mutations, delta G774 in exon 7 and delta AG1305-1306 in exon 11 (McInnes et al. 1992, Biochim. Biophys. Acta 1138: 315-317). Stop codons were generated in this cell line at codons 274 and 454, respectively. We took advantage of these genotypes to investigate the steady-state level of mRNA produced by cells containing stop codons using a competitive polymerase chain reaction technique. The mRNA levels were, as percent of normal per single gene dose: for the stop codon at codon 451, 30%; for those at codons 274 and 454, combined percentage of 1.7%; and at codon 284, 0.8%. These studies demonstrate a dramatic difference in the steady-state level of Hex beta mRNA in the cell lines with stop codons in close proximity to each other (codons 451 vs 454).(ABSTRACT TRUNCATED AT 250 WORDS)

The presence of two different infantile Tay-Sachs disease mutations in a Cajun population.

A study was undertaken to characterize the mutation(s) responsible for Tay-Sachs disease (TSD) in a Cajun population in southwest Louisiana and to identify the origins of these mutations. Eleven of 12 infantile TSD alleles examined in six families had the beta-hexosaminidase A (Hex A) alpha-subunit exon 11 insertion mutation that is present in approximately 70% of Ashkenazi Jewish TSD heterozygotes. The mutation in the remaining allele was a single-base transition in the donor splice site of the alpha-subunit intron 9. To determine the origins of these two mutations in the Cajun population, the TSD carrier status was enzymatically determined for 90 members of four of the six families, and extensive pedigrees were constructed for all carriers. A single ancestral couple from France was found to be common to most of the carriers of the exon 11 insertion. Pedigree data suggest that this mutation has been in the Cajun population since its founding over 2 centuries ago and that it may be widely distributed within the population. In contrast, the intron 9 mutation apparently was introduced within the last century and probably is limited to a few Louisiana families.

A pseudodeficiency allele common in non-Jewish Tay-Sachs carriers: implications for carrier screening.

Deficiency of beta-hexosaminidase A (Hex A) activity typically results in Tay-Sachs disease. However, healthy subjects found to be deficient in Hex A activity (i.e., pseudodeficient) by means of in vitro biochemical tests have been described. We analyzed the HEXA gene of one pseudodeficient subject and identified both a C739-to-T substitution that changes Arg247----Trp on one allele and a previously identified Tay-Sachs disease mutation on the second allele. Six additional pseudodeficient subjects were found to have the C739-to-T mutation. This allele accounted for 32% (20/62) of non-Jewish enzyme-defined Tay-Sachs disease carriers but for none of 36 Jewish enzyme-defined carriers who did not have one of three known mutations common to this group. The C739-to-T allele, together with a "true" Tay-Sachs disease allele, causes Hex A pseudodeficiency. Given both the large proportion of non-Jewish carriers with this allele and that standard biochemical screening cannot differentiate between heterozygotes for the C739-to-T mutations and Tay-Sachs disease carriers, DNA testing for this mutation in at-risk couples is essential. This could prevent unnecessary or incorrect prenatal diagnoses.

Six novel deleterious and three neutral mutations in the gene encoding the alpha-subunit of hexosaminidase A in non-Jewish individuals.

Initial investigations demonstrated that only 3/34 "Tay-Sachs chromosomes" in 22 unrelated, non-Jewish patients or carriers of some form of GM2-gangliosidosis (7 black and 15 non-Jewish Caucasian) had either of the two mutations commonly found in the Jewish population. To determine the nature and incidence of the alterations in this non-Jewish population we have utilized PCR, single-strand conformation polymorphism analysis and sequencing to detect new mutations in genomic DNA. Fourteen primer sets have been utilized to analyze 80% of the coding region and 23/26 splice sites of the gene coding for the alpha chain of hexosaminidase A. Presumed deleterious mutations were discovered in 17/34 chromosomes believed to be carrying a beta-hexosaminidase A alpha-subunit gene mutation. Ten had abnormalities which have been described previously. In the remaining 24 Tay-Sachs disease alleles, six novel mutations predicted to be deleterious were discovered. These include two small deletions (a single-base frameshift and a three-base deletion removing an amino acid), two different nonsense mutations, an initiation codon mutation (ATG----GTG), and a missense mutation (Arg499Cys) in a highly conserved residue. In addition, three presumed nondeleterious mutations were found.

Molecular basis of hexosaminidase A deficiency and pseudodeficiency in the Berks County Pennsylvania Dutch.

Following the birth of two infants with Tay-Sachs disease (TSD), a non-Jewish, Pennsylvania Dutch kindred was screened for TSD carriers using the biochemical assay. A high frequency of individuals who appeared to be TSD heterozygotes was detected (Kelly et al., 1975). Clinical and biochemical evidence suggested that the increased carrier frequency was due to at least two altered alleles for the hexosaminidase A alpha-subunit. We now report two mutant alleles in this Pennsylvania Dutch kindred, and one polymorphism. One allele, reported originally in a French TSD patient (Akli et al., 1991), is a GT-->AT transition at the donor splice-site of intron 9. The second, a C-->T transition at nucleotide 739 (Arg247Trp), has been shown by Triggs-Raine et al. (1992) to be a clinically benign "pseudodeficient" allele associated with reduced enzyme activity against artificial substrate. Finally, a polymorphism [G-->A (759)], which leaves valine at codon 253 unchanged, is described.

A mutation common in non-Jewish Tay-Sachs disease: frequency and RNA studies.

Tay-Sachs disease (TSD) is an autosomal recessive genetic disorder resulting from mutation of the HEXA gene encoding the alpha-subunit of the lysosomal enzyme, beta-N-acetylhexosaminidase A (Hex A). We have discovered that a Tay-Sachs mutation, IVS-9 + 1 G-->A, first detected by Akli et al. (Genomics 11:124-134, 1991), is a common disease allele in non-Jewish Caucasians (10/58 alleles examined). A PCR-based diagnostic test, which detects an NlaIII site generated by the mutation, revealed a frequency among enzyme-defined carriers of 9/64 (14%). Most of those carrying the allele trace their origins to the United Kingdom, Ireland, or Western Europe. It was not identified among 12 Black American TSD alleles or in any of 18 Ashkenazi Jewish, enzyme-defined carriers who did not carry any of the mutations common to this population. No normally spliced RNA was detected in PCR products generated from reverse transcription of RNA carrying the IVS-9 mutation. Instead, the low levels of mRNA from this allele were comprised of aberrant species resulting from the use of either of two cryptic donor sites, one truncating exon 9 and the other within IVS-9, spliced to exon 10. Numerous additional splice products were detected, most involving skipping of one or more surrounding exons. Together with a recently identified allele responsible for Hex A pseudodeficiency (Triggs-Raine et al. Am J Hum Genet, 1992), these two alleles accounted for almost 50% (29/64) of TSD or carrier alleles ascertained by enzyme screening tests in non-Jewish Caucasians.

A novel mutation in the invariant AG of the acceptor splice site of intron 4 of the beta-hexosaminidase alpha-subunit gene in two unrelated American black GM2-gangliosidosis (Tay-Sachs disease) patients.

Samples of genomic DNA from three unrelated American black infants having both biochemical and clinical features of classical infantile Tay-Sachs disease were sequenced following PCR amplification. A G----T transversion was observed in the AG acceptor splice site preceding exon 5 of the beta-hexosaminidase alpha-subunit gene in the first black family. This transversion changed the acceptor splice site from the consensus sequence, AG, to AT, thereby interfering with splicing at this intron 4/exon 5 junction. The proband was homozygous for this mutation; his mother and a brother are heterozygous. The same mutation was found in a second, apparently unrelated, black GM2-gangliosidosis patient. The second patient was a compound heterozygote, as only one allele carried this mutation. The mother and a brother in this second family are carriers for this mutation, while the father and a noncarrier sister are normal for this region of the gene. The third proband did not have this mutation; nor did the mother of a fourth black proband. Eight other independently ascertained non-black, non-Jewish, GM2-gangliosidosis families did not have this mutation. The observation of the same novel mutation in two unrelated black GM2-gangliosidosis patients indicates that the American black population has segregating within it at least one GM2-gangliosidosis mutation which may be specific to this population and not a result of migration.

Cancer in relatives of leukemic patients with chromosomal rearrangements at rare (heritable) fragile-site locations in their malignant cells.

The cancer occurrence in relatives (N = 407) of 40 case probands (who had leukemia and rearrangements at the same chromosomal location as at least one of 23 recognized rare [heritable] autosomal fragile sites [Sutherland and Mattei 1987]) was compared both to cancer occurrence in relatives (N = 390) of 40 control probands (who had leukemia or other hematologic illness but no recognized chromosomal rearrangements) and to cancer incidence in the general population of the United States. Fragile-site carrier status was not determined in case or control probands. No significant excess of cancer in case relatives, compared with either control relatives or to general (SEER) population expectancies, was found. Furthermore, there was neither evidence of cancer at younger ages, when cases were compared with control relatives, nor an excess of cancer at multiple sites. Male relatives of cases did, however, show a small excess of cancer, especially in older age groups. There was a slight, but not statistically significant, excess of lung cancer in case relatives, with this deviation occurring almost exclusively in relatives of probands having rearrangements at 11q23 and having lymphoid leukemia. It is possible that heritable tendency to chromosomal rearrangement--and thus to cancer--is expressed in such a small proportion of family members that cancer excess in these families could not be detected with the numbers of relatives analyzed in this study, although there was no significant evidence for a hereditary predisposition to cancer in the families of probands with leukemia and with chromosomal rearrangements at the same apparent chromosomal location as rare fragile sites.

Familial isolated aniridia associated with a translocation involving chromosomes 11 and 22 [t(11;22)(p13;q12.2)].

Isolated aniridia segregated as an autosomal dominant trait in a family with 11 affected members spanning five generations. Four of the eight individuals studied had aniridia associated with glaucoma and cataracts. Cytogenetic studies revealed an apparently balanced reciprocal translocation between chromosomes 11 and 22 [t(11;22)(p13;q12.2)], while four unaffected relatives had normal karyotypes. There is no evidence of Wilms tumor or genitourinary abnormalities in any members of the family. Restriction enzyme analysis of the human catalase gene revealed no abnormalities in the individuals with the translocation. A summary of phenotypic abnormalities in 61 cases associated with aniridia is presented, as well as a comparison of breakpoints in 44 cases of 11p deletion. These data indicate that single breaks at 11p13 are associated with isolated aniridia, while deletion of 11p13 results in aniridia combined with Wilms tumor, genitourinary abnormalities, and/or mental retardation.

Reproductive outcomes of paracentric inversion carriers: report of a liveborn dicentric recombinant and literature review.

An abnormal infant had a dicentric chromosome 14 with an inverted tandem duplication [46,XY,inv dup(14) (pter----q32.3::q24.2----pter)], thus making him trisomic for the proximal two-thirds of chromosome 14. This abnormality was derived from a maternal paracentric inversion in chromosome 14 [46,XX,inv(14)(q24.2q32.3)]. To our knowledge, this is the first report of a liveborn infant carrying a stable, dicentric product of crossing over within a paracentric inversion loop. A review of the reproductive outcomes of paracentric inversion carriers in the literature suggests that they are at some risk for pregnancy wastage. The risk for liveborn recombinants is small but such births have occurred, at least to female carriers.

Two different structural abnormalities of chromosome 13 in offspring of chromosomally normal parents with two fragile sites.

Two siblings were found with different structural abnormalities involving their maternally inherited chromosome 13. The proband exhibited a ring 13 and a small fragment: 46,XX,r(13) (p11q34), +f, while her clinically normal brother carried a dicentric Robertsonian translocation: 45,XY,dic(13;15) (p11;p11). Both parents had normal karyotypes in peripheral blood and skin fibroblasts. The structural abnormalities of chromosome 13 may be due to an unstable gonadal 13;15 translocation in the mother. In addition, two autosomal fragile sites were segregating in this family. The mother had a fragile (16) (q22) which was inherited by the proband. The father and paternal grandmother possessed a fragile (12)(q13) which was not inherited by either child. The expression of both fragile sites was dependent on culture conditions.