Etiological heterogeneity in X-linked spastic paraplegia.

We describe a large family (K313) having 12 males affected with X chromosome-linked recessive hereditary spastic paraplegia (HSP). The disease phenotype in K313 is characterized by hyperreflexia and a spastic gait, but intelligence is normal. Carrier females have normal gait and unremarkable neurologic profiles. Eight widely spaced X-linked DNA markers were used to genotype 43 family members. In contrast to a published study of another family, in whom complete linkage of X-linked recessive HSP to distal chromosome Xq markers DXS15 and DXS52 was reported, we observed complete linkage with two DNA markers, pYNH3 and DXS17, located on the middle of the long arm of the X chromosome. These data have been combined with linkage data from a large reference panel of normal families to localize the new X-chromosome marker, pYNH3, and to provide evidence of significant locus heterogeneity between phenotypically distinct forms of X-linked recessive HSP.     

Rapid resolution of duck hepatitis B virus infections occurs after massive hepatocellular involvement.

A study was carried out to determine some of the factors that might distinguish transient from chronic hepadnavirus infection. First, to better characterize chronic infection, Pekin ducks, congenitally infected with the duck hepatitis B virus (DHBV), were used to assess age-dependent variations in viremia, percentage of DHBV-infected hepatocytes, and average levels of DNA replication intermediates in the cytoplasm and of covalently closed circular DNA in the nuclei of infected hepatocytes. Levels of viremia and viral DNA were found to peak at about the time of hatching but persisted at relatively constant levels in chronically infected birds up to 2 years of age. The percentage of infected hepatocytes was also constant, with DHBV replication in virtually 100% of hepatocytes in all birds. Next, we found that adolescent ducks inoculated intravenously with a large dose of DHBV also developed massive infection of hepatocytes with an early but low-level viremia, followed by rapid development of a neutralizing antibody response. No obvious quantitative or qualitative differences between transiently and chronically infected liver tissue were detected in the intracellular markers of viral replication examined. However, in the adolescent duck experiment, DHBV infection was rapidly cleared from the liver even when up to 80% of hepatocytes were initially infected. In all of these ducks, clearance of infection was accompanied by only a mild hepatitis, with no evidence that massive cell death contributed to the clearance. This finding suggested that mechanisms in addition to immune-mediated destruction of hepatocytes might make major contributions to clearance of infections, including physiological turnover of hepatocytes in the presence of a neutralizing antibody response and/or spontaneous loss of the capacity of hepatocytes to support virus replication.     

Characterization of AmphiF-spondin reveals the modular evolution of chordate F-spondin genes

The F-spondin genes are a family of extracellular matrix molecules united by two conserved domains, FS1 and FS2, at the amino terminus plus a variable number of thrombospondin repeats at the carboxy terminus. Currently, characterized members include a single gene in Drosophila and multiple genes in vertebrates. The vertebrate genes are expressed in the midline of the developing embryo, primarily in the floor plate of the neural tube. To investigate the evolution of chordate F-spondin genes, I have used the basal position in chordate phylogeny of the acraniate amphioxus. A single F-spondin-related gene, named AmphiF-spondin, was isolated from amphioxus. Based on molecular phylogenetics, AmphiF-spondin is closely related to a particular subgroup of vertebrate F-spondin genes that encode six thrombospondin repeats. However, unlike these genes, expression of AmphiF-spondin is not confined to the midline but is found through most of the central nervous system. Additionally, AmphiF-spondin has lost three thrombospondin repeats and gained two fibronectin type III repeats, one of which has strong identity to a fibronectin type III repeat from Deleted in Colorectal Cancer (DCC). Taken together, these results suggest a complex evolutionary history for chordate F-spondin genes that includes (1) domain loss, (2) domain gain by tandem duplication and divergence of existing domains, and (3) gain of heterologous domains by exon shuffling.      

Genetic linkage and heterogeneity in type I Charcot-Marie-Tooth disease (hereditary motor and sensory neuropathy type I).

The segregation patterns of DNA markers from the pericentromeric regions of chromosomes 1 and 17 were studied in seven pedigrees segregating an autosomal dominant gene for Charcot-Marie-Tooth neuropathy type I (CMT I; hereditary motor and sensory neuropathy I). A multilocus analysis with four markers (pMCR-3, pMUC10, FY, and pMLAJ1) spanning the pericentromeric region of chromosome 1 excluded the CMT I gene from this region in six pedigrees but gave some evidence for linkage to the region of Duffy in one pedigree. Linkage of the CMT I gene to markers in the pericentromeric region of chromosome 17 (markers pA10-41, pEW301, p3.6, and pTH17.19) was established; however, in these seven pedigrees homogeneity analysis with chromosome 17 markers detected significant genetic heterogeneity. This analysis suggested that three of the seven pedigrees are not linked to this same region. Overall, two of the seven CMT I pedigrees were not linked to markers tested from chromosomes 1 or 17. These results confirm genetic heterogeneity in CMT I and implicate the existence of a third autosomal locus, in addition to a locus on chromosome 17, and a probable locus on chromosome 1. This evidence of etiological heterogeneity, supported by statistical tests, will have to be taken into consideration when fine-structure genetic maps of the regions around CMT I are constructed.     

Diagnosis of neurofibromatosis I by using tightly linked, flanking DNA markers.

We tested 132 individuals from 21 families segregating an allele for neurofibromatosis type 1 (NF-1), by using nine RFLPs tightly linked to the NF-1 locus. Family members had requested DNA testing either to determine whether "at risk" children were carrying the NF-1 allele or to determine whether their respective families would be informative for prenatal testing. Predictions about whether a child carries the NF-1 mutation were possible for all 32 at-risk offspring (greater than 98% accuracy based on the recombination estimates currently available for these DNA markers). At least one informative probe was available for all 23 matings in these 21 families; flanking markers were informative for 10 matings. Pairwise analysis showed that several of the polymorphisms were in tight linkage disequilibrium; few recombination events were observed with these markers in the families under study. We conclude that the DNA probes used in this study perform well for diagnostic testing of NF-1 in familial cases. A subset of five probe-enzyme systems (pHHH202/RsaI, p11-3C4.2/MspI, pTH17.19/Bg/II, p11-2C11.7/BamHI, and p11-2F9.8/TaqI) provide reliable linkage information for both clinical testing and prenatal diagnosis.     

PRB2/1 fusion gene: a product of unequal and homologous crossing-over between proline-rich protein (PRP) genes PRB1 and PRB2.

The PRB2/1 fusion gene is produced by homologous and unequal crossing-over between PRB1 and PRB2 genes that code for basic salivary proline-rich proteins (PRPs). To determine the molecular basis for the PRB2/1 fusion gene, the DNA sequence was determined for the PRB2/1 gene and was compared with those of the PRB1 and PRB2 genes. From these comparisons, the crossing-over is postulated to occur in a 743-bp region of identity, with only 1-bp mismatch between the PRB1 and PRB2 genes, in the third intron outside the coding region of the two genes. This region of virtual complete identity is the largest found between any of the six closely linked PRB genes and may facilitate recombination. Since the coding region of PRB1 is completely absent from the PRB2/1 gene, salivas from two white PRB2/1 homozygotes were studied to determine which polymorphic PRPs were missing from the salivas. Polymorphic PRPs Pe, PmF, PmS, and Ps were found to be missing from the salivas. However, a white individual lacking the same salivary PRPs is a PRB2/1 heterozygote with one PRB1 allele. The explanation for the missing salivary proteins in this individual is unknown. The PRB2/1 gene is relatively frequent in several populations of unrelated individuals, including American blacks (n = 41), American Utah whites (n = 76), and mainland Chinese (n = 131), with gene frequencies of .22, .06, and .09, respectively. Evidence for the occurrence of PRB1/2 heterozygotes is also presented.     

Transmission potential,skin inflammatory response,and parasitism of symptomatic and asymptomatic dogs with visceral leishmaniasis

Background

Visceral leishmaniasis in Brazil is caused by the protozoan Leishmania (Leishmania) chagasi and it is transmitted by sandfly of the genus Lutzomyia. Dogs are an important domestic reservoir, and control of the transmission of visceral leishmaniasis (VL) to humans includes the elimination of infected dogs. However, though dogs are considered to be an important element in the transmission cycle of Leishmania, the identification of infected dogs representing an immediate risk for transmission has not been properly evaluated. Since it is not possible to treat infected dogs, they are sacrificed when a diagnosis of VL is established, a measure that is difficult to accomplish in highly endemic areas. In such areas, parameters that allow for easy identification of reservoirs that represents an immediate risk for transmission is of great importance for the control of VL transmission. In this study we aimed to identify clinical parameters, reinforced by pathological parameters that characterize dogs with potential to transmit the parasite to the vector.

Results

The major clinical manifestations of visceral leishmaniasis in dogs from an endemic area were onicogriphosis, skin lesions, conjunctivitis, lymphadenopathy, and weight loss. The transmission potential of these dogs was assessed by xenodiagnosis using Lutzomyia longipalpis. Six of nine symptomatic dogs were infective to Lutzomyia longipalpis while none of the five asymptomatic dogs were infective to the sandfly. Leishmania amastigotes were present in the skin of all clinically symptomatic dogs, but absent in asymptomatic dogs. Higher parasite loads were observed in the ear and ungueal region, and lower in abdomen. The inflammatory infiltrate was more intense in the ears and ungueal regions of both symptomatic and asymptomatic dogs. In clinically affected dogs in which few or none Leishmania amastigotes were observed, the inflammatory infiltrate was constituted mainly of lymphocytes and macrophages. When many parasites were present, the infiltrate was also comprised of lymphocytes and macrophages, as well as a larger quantity of polymorphonuclear neutrophils (PMNs).

Conclusion

Dogs that represent an immediate risk for transmission of Leishmania in endemic areas present clinical manifestations that include onicogriphosis, skin lesions, conjunctivitis, lymphadenopathy, and weight loss. Lymphadenopathy in particular was a positive clinical hallmark since it was closely related to the positive xenodiagnosis.

     

Effects of age,replicative lifespan and growth rate of human nucleus pulposus cells on selecting age range for cell-based biological therapies for degenerative disc diseases

Autologous disc cell implantation, growth factors and gene therapy appear to be promising therapies for disc regeneration. Unfortunately, the replicative lifespan and growth kinetics of human nucleus pulposus (NP) cells related to host age are unclear. We investigated the potential relations among age, replicative lifespan and growth rate of NP cells, and determined the age range that is suitable for cell-based biological therapies for degenerative disc diseases. We used NP tissues classified by decade into five age groups: 30s, 40s, 50s, 60s and 70s. The mean cumulative population doubling level (PDL) and population doubling rate (PDR) of NP cells were assessed by decade. We also investigated correlations between cumulative PDL and age, and between PDR and age. The mean cumulative PDL and PDR decreased significantly in patients in their 60s. The mean cumulative PDL and PDR in the younger groups (30s, 40s and 50s) were significantly higher than those in the older groups (60s and 70s). There also were significant negative correlations between cumulative PDL and age, and between PDR and age. We found that the replicative lifespan and growth rate of human NP cells decreased with age. The replicative potential of NP cells decreased significantly in patients 60 years old and older. Young individuals less than 60 years old may be suitable candidates for NP cell-based biological therapies for treating degenerative disc diseases.