Significance of premature stop codons in env of simian immunodeficiency virus.

The location of the translational termination codon for the transmembrane protein (TMP) varies in three infectious molecular clones of simian immunodeficiency virus from macaques (SIVmac). The SIVmac251 and SIVmac142 infectious clones have premature stop signals that differ in location by one codon; transfection of these DNAs into human HUT-78 cells yielded virus with a truncated TMP (28 to 30 kilodaltons [kDa]). The SIVmac239 infectious clone does not have a premature stop codon in its TMP-coding region. Transfection of HUT-78 cells with this clone initially yielded virus with a full-length TMP (41 kDa). At 20 to 30 days posttransfection, SIVmac239 virus with a 41-kDa TMP gradually disappeared coincident with the emergence of a virus with a 28-kDa TMP. Virus production dramatically increased in parallel with the emergence of a virus with a 28-kDa TMP. Sequence analysis of viral DNAs from these cultures showed that premature stop codons arising by point mutation were responsible for the change in size of the TMP with time. A similar selective pressure for truncated forms of TMP was observed when the SIVmac239 clone was transfected into human peripheral blood lymphocytes (PBL). In contrast, no such selective pressure was observed in macaque PBL. When the SIVmac239 clone was transfected into macaque PBL and the resultant virus was serially passaged in macaque PBL, the virus replicated very well and maintained a 41-kDa TMP for 80 days in culture. Macaque monkeys were infected with SIVmac239 having a 28-kDa TMP; virus subsequently recovered from T4-enriched lymphocytes of peripheral blood showed only the 41-kDa form of TMP. These results indicate that the natural form of TMP in SIVmac is the full-length 41-kDa TMP, just as in human immunodeficiency virus type 1. Viruses with truncated forms of TMP appear to result from mutation and selection during propagation in unnatural human cells.     

Strain-specific neutralizing determinant in the transmembrane protein of simian immunodeficiency virus.

Monoclonal antibody SF8/5E11, which recognizes the transmembrane protein (TMP) of simian immunodeficiency virus of macaque monkeys (SIVmac), displayed strict strain specificity. It reacted with cloned and uncloned SIVmac251 but not with cloned SIVmac142 and SIVmac239 on immunoblots. This monoclonal antibody neutralized infection by cloned, cell-free SIVmac251 and inhibited formation of syncytia by cloned SIVmac251-infected cells; these activities were specific to cloned SIVmac251 and did not occur with the other viruses. Site-specific mutagenesis was used to show that TMP amino acids 106 to 110 (Asp-Trp-Asn-Asn-Asp) determined the strain specificity of the monoclonal antibody. This strain-specific neutralizing determinant is located within a variable region of SIVmac and human immunodeficiency virus type 2 (HIV-2) which includes conserved, clustered sites for N-linked glycosylation. The determinant corresponds exactly to a variable, weak neutralizing epitope in HIV-1 TMP which also includes conserved, clustered sites for N-linked glycosylation. Thus, the location of at least one neutralizing epitope appears to be common to both SIVmac and HIV-1. Our results suggest a role for this determinant in the viral entry process. Genetic variation was observed in this neutralizing determinant following infection of a rhesus monkey with molecularly cloned SIVmac239; variant forms of the strain-specific, neutralizing determinant accumulated during persistent infection in vivo. Selective pressure from the host immune response in vivo may result in sequence variation in this neutralizing determinant.     

Truncation of the cytoplasmic domain of the simian immunodeficiency virus envelope glycoprotein increases env incorporation into particles and fusogenicity and infectivity.

Growth of macaque simian immunodeficiency virus (SIVmac) in certain cloned human T-cell lines, such as HUT.78, selects for isolates containing a premature stop codon within the cytoplasmic domain of the transmembrane envelope glycoprotein. In contrast, propagation of virus in macaques or in their cultured T cells favors replication of virus containing the full-length envelope glycoprotein. To elucidate the causes of this phenomenon, we used a human immunodeficiency virus pseudotyping system to assess the effects on infectivity of the cytoplasmic domains of envelope glycoproteins obtained from SIVmac1A11 and SIVmac239. These envelopes contain truncated and full-length cytoplasmic domains, respectively. By analyzing human immunodeficiency virus particles containing selectable genes pseudotyped with each glycoprotein or with chimeric derivatives, we found that truncation of the cytoplasmic domain resulted in a significant advantage in viral entry into HUT.78 T cells and CD4+ U87.MG glial cells. Truncation of the cytoplasmic domain significantly enhanced both envelope density on particles and envelope-mediated cell-to-cell fusion. It is likely that one or both of these effects contribute to the observed differences in infectivity and to the selection of virions with short cytoplasmic tails in human T cells.     

Characterization of infectious molecular clones of simian immunodeficiency virus (SIVmac) and human immunodeficiency virus type 2: persistent infection of rhesus monkeys with molecularly cloned SIVmac.

Infection of macaque monkeys with simian immunodeficiency virus (SIV) is probably the best animal model currently available for studying acquired immunodeficiency syndrome. In this report, we describe three infectious molecular clones of SIVmac and one of human immunodeficiency virus type 2 (HIV-2) and their use in the study of cell and species specificity, animal infection, and the relationship of gene sequence to function. Replication of the cloned viruses in different cell lines varied dramatically. Some human CD4+ cell lines (HUT 78 and MT-4) supported the replication of SIVmac and HIV-2, while others (CEM and Jurkat-T) supported the replication of HIV-2 but not SIVmac. Growth of cloned virus in macaque lymphocytes in vitro was predictive of macaque infection in vivo. Macaque lymphocytes supported the replication of SIVmac239 and SIVmac251 but not SIVmac142 or HIV-2ROD. Using virus recovery and antibody response as criteria for infection, macaques that received cloned SIVmac251 and SIVmac239 became infected, while macaques receiving cloned SIVmac142 and HIV-2ROD did not become infected. Nucleotide sequences from the envelope region of all four cloned viruses demonstrated that there is considerable flexibility in the location of the translational termination (stop) signal. These infectious molecular clones will be very useful for future studies directed at the molecular basis for persistence, pathogenicity, tropism, and cell and species specificity.     

Nef genes of SIV

Molecular clones of SIVmac were constructed that differed only in sequences within the nef gene. DEAE-transfection of viral DNA containing an open from of nef yielded virus that replicated with similar kinetics and to a similar extent in macaque peripheral blood lymphocyte (PBL) cultures as virus with a deletion or stop codon within nef. Rhesus monkeys that received each kind of molecularly cloned virus became infected. Our results additionally suggest that mutant forms of virus are selected in vitro while open, functional forms are selected in vivo. In animals infected with virus containing a stop codon within nef, reversion of the stop codon to a coding codon was demonstrated in five of five clones analyzed. These results indicate that nef is playing some role crucial to the virus life cycle in vivo.     

The cytoplasmic domain of simian immunodeficiency virus transmembrane protein modulates infectivity.

A striking characteristic of the simian immunodeficiency virus (SIV) and of the human immunodeficiency virus type 2 (HIV-2) is the presence of a nonsense mutation in the env gene resulting in the synthesis of a truncated transmembrane protein lacking the cytoplasmic domain. By mutagenesis of an infectious molecular clone of SIVmac142, we investigated the function of the cytoplasmic domain and the significance of the env nonsense mutation. When the nonsense codon (TAG) was replaced by a glutamine codon (CAG), the virus infected HUT78 cells with markedly delayed kinetics. This negative effect was counterselected in vitro as reversion of the slow phenotype frequently occurred. The sequencing of one revertant revealed the presence of a new stop codon three nucleotides 5' to the original mutation. Deletions or an additional nonsense mutation introduced 3' to the original stop codon did not modify SIV infectivity. In contrast, the same deletions or nonsense mutation introduced in the clone in which the stop codon was replaced by CAG abolished infectivity. These results indicated that the envelope domain located 3' to the stop codon is not necessary for in vitro replication. However, the presence of this domain in SIV transmembrane protein leads to a reduced infectivity. This negative effect might correspond to a function controlling the rate of spread of the virus during in vivo infection.     

Simian immunodeficiency virus from African green monkeys.

Simian immunodeficiency virus (SIV) was isolated from the total peripheral blood mononuclear cell population and the monocyte-macrophage adherent cell population of three seropositive green monkeys originating from Kenya. SIV from these African green monkeys (SIVagm) was isolated and continuously produced with the MOLT-4 clone 8 (M4C18) cell line but not with a variety of other cells including HUT-78, H9, CEM, MT-4, U937, and uncloned MOLT-4 cells. Once isolated, these SIVagm isolates were found to replicate efficiently in M4C18, SupT1, MT-4, U937, and Jurkat-T cells but much less efficiently if at all in HUT-78, H9, CEM, and MOLT-4 cells. The range of CD4+ cells fully permissive for replication of these SIVagm isolates thus differs markedly from that of previous SIV isolates from macaques (SIVmac). These SIVagm isolates had a morphogenesis and morphology like that of human immunodeficiency virus (HIV) and other SIV isolates. Antigens of SIVagm and SIVmac cross-reacted by comparative enzyme-linked immunosorbent assay only with reduced efficiency, and optimal results were obtained when homologous antibody and antigen were used. Western blotting (immunoblotting) of purified preparations of SIVagm isolate 385 (SIVagm385) revealed major viral proteins of 120, 27, and 16 kilodaltons (kDa). The presumed major core protein of 27 kDa cross-reacted antigenically with the corresponding proteins of SIVmac (28 kDa) and HIV-1 (24 kDa) by Western blotting. Hirt supernatant replicative-intermediate DNA prepared from cells freshly infected with SIVagm hybridized to SIVmac and HIV-2 DNA probes. Detection of cross-hybridizing DNA sequences, however, required very low stringency, and the restriction endonuclease fragmentation patterns of SIVagm were not similar to those of SIVmac and HIV-2. The nucleotide sequence of a portion of the pol gene of SIVagm385 revealed amino acid identities of 65% with SIVmac142, 64% with HIV-2ROD, and 56% with HIV-1BRU; SIVagm385 is thus related to but distinct from previously described primate lentiviruses SIVmac, HIV-1, and HIV-2. Precise information on the genetic makeup of these and other SIV isolates will possibly lead to better understanding of the history and evolution of these viruses and may provide insight into the origin of viruses that cause acquired immunodeficiency syndrome in humans.     

The molecular basis of truncated forms of apolipoprotein B in a kindred with compound heterozygous hypobetalipoproteinemia

Krul et al. (1) have identified two truncated species of apolipoprotein B-100 in a kindred with familial hypobetalipoproteinemia. Five family members were identified who produce either one or both of two truncated apolipoprotein B-100 proteins estimated to be 40% and 90% the amino-terminal end of apolipoprotein B-100. Low density lipoprotein with the apolipoprotein B-90 binds more strongly to the low density lipoprotein-receptor on cultured fibroblasts. In this present study, we have identified the DNA mutations leading to these truncated apolipoprotein B-100 variants in this kindred. Sequencing of amplified DNA from the proband revealed that deletions of one or two nucleotide bases produced frameshift mutations and generated premature stop codons in both cases. Apolipoprotein B-40 (Val1829----Cys-TERM) is the result of a dinucleotide (TG) deletion in exon 26 that generates a stop codon at position 1830 and produces a protein with a predicted molecular mass of 207.14 kDa. The other truncated apolipoprotein B Glu4034----Arg-Gln-Leu-Leu-Ala-Cys-TERM) is due to a single nucleotide (G) deletion in exon 29. This results in a protein with 4039 amino acids and a predicted molecular mass of 457.6 kDa that is now designated apolipoprotein B-89. Mechanisms by which the removal of the last 497 amino acids might increase the binding of the apoB-89 to the LDL-receptor are discussed.     

Point mutation in the human dystrophin gene: identification through western blot analysis

Using antibodies directed against the amino-terminus of dystrophin, we identified a truncated protein in a Duchenne muscular dystrophy patient. Antibodies directed against the carboxy-terminus failed to identify any cross-reactive material, a result consistent with premature termination of dystrophin translation. The estimated molecular mass of 126 kDa predicted the approximate location of the mutation in the mRNA and in the gene. Sequencing of cloned PCR products from patient muscle cDNA revealed a nonsense mutation, which was confirmed by direct sequencing of amplified patient genomic DNA. The mutation, a G to T transversion, at position 3714 changes a glutamic acid codon to an Amber stop codon. Translation of mRNA containing this mutation would be expected to result in a truncated protein with a molecular mass of 133 kDa, in close agreement with the 126 kDa estimated by Western blot analysis. This is the first reported case of a point mutation in this very large human gene.     

Identification and NH2-terminal amino acid sequence of three insulin-like growth factor-binding proteins in porcine serum.

Three distinct species of IGFBP in porcine serum were identified by NH2-terminal amino acid sequence analysis. The IGFBPs identified include pIGFBP-2 (34 kDa), three isoforms of pIGFBP-3 (43, 40 and 30 kDa) and two isoforms of pIGFBP-4 (30 and 26 kDa). The three isoforms of pIGFBP-3 were found to have a common NH2-terminal amino acid sequence, as were the two isoforms of pIGFBP-4. These results indicate that porcine serum contains a truncated form of IGFBP-3 and two forms of pIGFBP-4, similar to those previously isolated from human and rat serum. Furthermore, the presence of a truncated form(s) of the GH-dependent IGFBP-3 in porcine serum suggests that elucidating its origin and function may be important in understanding how IGFBPs affect the somatogenic actions of GH.     

C-terminal truncated forms of Met, the hepatocyte growth factor receptor.

The MET proto-oncogene encodes a transmembrane tyrosine kinase of 190 kDa (p190MET), which has recently been identified as the receptor for hepatocyte growth factor/scatter factor. p190MET is a heterodimer composed of two disulfide-linked chains of 50 kDa (p50 alpha) and 145 kDa (p145 beta). We have produced four different monoclonal antibodies that are specific for the extracellular domain of the Met receptor. These antibodies immunoprecipitate with p190MET two additional Met proteins of 140 and 130 kDa. The first protein (p140MET) is membrane bound and is composed of an alpha chain (p50 alpha) and an 85-kDa C-terminal truncated beta chain (p85 beta). The second protein (p130MET) is released in the culture supernatant and consists of an alpha chain (p50 alpha) and a 75-kDa C-terminal truncated beta chain (p75 beta). Both truncated forms lack the tyrosine kinase domain. p140MET and p130MET are consistently detected in vivo, together with p190MET, in different cell lines or their culture supernatants. p140MET is preferentially localized at the cell surface, where it is present in roughly half the amount of p190MET. The two C-terminal truncated forms of the Met receptor are also found in stable transfectants expressing the full-length MET cDNA, thus showing that they originate from posttranslational proteolysis. This process is regulated by protein kinase C activation. Together, these data suggest that the production of the C-terminal truncated Met forms may have a physiological role in modulating the Met receptor function.     

Proteolytic modification of membrane-associated phospholipase C-β by μ-calpain enhances its activation by G-protein βγ subunits in human platelets

Membrane-associated phosphoinositide-phospholipase C (PI-PLC)-β (150 kDa) and its truncated forms (100 kDa and 45 kDa) were purified from human platelets. The 100 kDa PI-PLC-β was found to be activated to a greater extent by brain G-protein βγ subunits compared to the intact 150 kDa enzyme. Furthermore, treatment with μ-calpain of the intact PI-PLC-β (150 kDa) caused a marked augmentation of its activation by βγ subunits. This enhanced PLC activation by βγ subunits was due to truncation by μ-calpain, producing a 100 kDa PI-PLC, but not by another protease,thrombin.     

In vivo attenuation of simian immunodeficiency virus by disruption of a tyrosine-dependent sorting signal in the envelope glycoprotein cytoplasmic tail

Attenuated simian immunodeficiency viruses (SIVs) have been described that produce low levels of plasma virion RNA and exhibit a reduced capacity to cause disease. These viruses are particularly useful in identifying viral determinants of pathogenesis. In the present study, we show that mutation of a highly conserved tyrosine (Tyr)-containing motif (Yxxphi) in the envelope glycoprotein (Env) cytoplasmic tail (amino acids YRPV at positions 721 to 724) can profoundly reduce the in vivo pathogenicity of SIVmac239. This domain constitutes both a potent endocytosis signal that reduces Env expression on infected cells and a sorting signal that directs Env expression to the basolateral surface of polarized cells. Rhesus macaques were inoculated with SIVmac239 control or SIVmac239 containing either a Tyr-721-to-Ile mutation (SIVmac239Y/I) or a deletion of Tyr-721 and the preceding glycine (DeltaGY). To assess the in vivo replication competence, all viruses contained a stop codon in nef that has been shown to revert during in vivo but not in vitro replication. All three control animals developed high viral loads and disease. One of two animals that received SIVmac239Y/I and two of three animals that received SIVmac239DeltaGY remained healthy for up to 140 weeks with low to undetectable plasma viral RNA levels and normal CD4(+) T-cell percentages. These animals exhibited ongoing viral replication as determined by detection of viral sequences and culturing of mutant viruses from peripheral blood mononuclear cells and persistent anti-SIV antibody titers. In one animal that received SIVmac239Y/I, the Ile reverted to a Tyr and was associated with a high plasma RNA level and disease, while one animal that received SIVmac239DeltaGY also developed a high viral load that was associated with novel and possibly compensatory mutations in the TM cytoplasmic domain. In all control and experimental animals, the nef stop codon reverted to an open reading frame within the first 2 months of inoculation, indicating that the mutant viruses had replicated well enough to repair this mutation. These findings indicate that the Yxxphi signal plays an important role in SIV pathogenesis. Moreover, because mutations in this motif may attenuate SIV through mechanisms that are distinct from those caused by mutations in nef, this Tyr-based sorting signal represents a novel target for future models of SIV and human immunodeficiency virus attenuation that could be useful in new vaccine strategies.     

Characterization of truncated forms of abnormal prion protein in Creutzfeldt-Jakob disease

In prion disease, the abnormal conformer of the cellular prion protein, PrP(Sc), deposits in fibrillar protein aggregates in brain and other organs. Limited exposure of PrP(Sc) to proteolytic digestion in vitro generates a core fragment of 19-21 kDa, named PrP27-30, which is also found in vivo. Recent evidence indicates that abnormal truncated fragments other than PrP27-30 may form in prion disease either in vivo or in vitro. We characterized a novel protease-resistant PrP fragment migrating 2-3 kDa faster than PrP27-30 in Creutzfeldt-Jakob disease (CJD) brains. The fragment has a size of about 18.5 kDa when associated with PrP27-30 type 1 (21 kDa) and of 17 kDa when associated with type 2 (19 kDa). Molecular mass and epitope mapping showed that the two fragments share the primary N-terminal sequence with PrP27-30 types 1 and 2, respectively, but lack a few amino acids at the very end of C terminus together with the glycosylphosphatidylinositol anchor. The amounts of the 18.5- or 17-kDa fragments and the previously described 13-kDa PrP(Sc) C-terminal fragment relatively to the PrP27-30 signal significantly differed among CJD subtypes. Furthermore, protease digestion of PrP(Sc) or PrP27-30 in partially denaturing conditions generated an additional truncated fragment of about 16 kDa only in typical sporadic CJD (i.e. MM1). These results show that the physicochemical heterogeneity of PrP(Sc) in CJD extends to abnormal truncated forms of the protein. The findings support the notion of distinct structural "conformers" of PrP(Sc) and indicate that the characterization of truncated PrP(Sc) forms may further improve molecular typing in CJD.     

Human Brain βA4 Amyloid Protein Precursor of Alzheimer''s Disease: Purification and Partial Characterization

The major component of the amyloid deposition that characterizes Alzheimer's disease is the 4-kDa beta A4 protein, which is derived from a much larger amyloid protein precursor (APP). A procedure for the complete purification of APP from human brain is described. The same amino terminal sequence of APP was found in two patients with Alzheimer's disease and one control subject. Two major forms of APP were identified in human brain with apparent molecular masses of 100-110 kDa and 120-130 kDa. Soluble and membrane fractions of brain contained nearly equal amounts of APP in both humans and rats. Immunoprecipitation with carboxyl terminus-directed antibodies indicates that the soluble forms of APP are truncated. Carboxyl terminus truncation of membrane-associated forms of human brain APP was also found to occur during postmortem autolysis. The availability of purified human brain APP will facilitate the investigation of its normal function and the events that lead to its abnormal cleavage in patients with Alzheimer's disease.     

Importance of vpr for infection of rhesus monkeys with simian immunodeficiency virus.

The importance of the vpr gene for simian immunodeficiency virus (SIV) replication, persistence, and disease progression was examined by using the infectious pathogenic molecular clone called SIVmac239. The ATG start codon of the vpr gene was converted to TTG by site-specific mutagenesis. The constructed Vpr- mutant virus is identical with the parental SIVmac239/nef-stop virus with the exception of this one nucleotide. These viruses replicated with similar kinetics and to similar extents in rhesus monkey lymphocyte cultures and in the human CEMX174 cell line. Five rhesus monkeys were inoculated with the Vpr- variant of SIVmac239/nef-stop, and two monkeys received SIVmac239/nef-stop as controls. Both controls showed reversion of the TAA stop signal in nef by 2 weeks postinfection, as has been observed previously. Reversion of the TAA stop codon in nef also occurred in the five monkeys that received the Vpr- variant, but reversion was delayed on average to about 4 weeks. Thus, the mutation in vpr appeared to delay the rapidity with which reversion occurred in the nef gene. Reversion of the TTG sequence in vpr to ATG was observed in three of the five test animals. Reversion in vpr was first observed in these three animals 4 to 8 weeks postinfection. No vpr revertants were found over the entire 66 weeks of observation in the other two test animals that received the vpr mutant. Antibodies to vpr developed in those three animals in which reversion of vpr was documented, but antibodies to vpr were not observed in the two animals in which reversion of vpr was not detected. Antibody responses to gag and to whole virus antigens were of similar strength in all seven animals. Both control animals and two of the test animals in which vpr reverted maintained high virus loads and developed progressive disease. Low virus burden and no disease have been observed in the two animals in which vpr did not revert and in the one animal in which vpr reversion was first detected only at 8 weeks. The reversion of vpr in three of the five test animals indicates that there is significant selective pressure for functional forms of vpr in vivo. Furthermore, the results suggest that both vpr and nef are important for maximal SIV replication and persistence in vivo and for disease progression.