Debbie Ang

Mitochondrial Hsp60 Chaperonopathy Causes an Autosomal-Recessive Neurodegenerative Disorder Linked to Brain Hypomyelination and Leukodystrophy

Hypomyelinating leukodystrophies (HMLs) are disorders involving aberrant myelin formation. The prototype of primary HMLs is the X-linked Pelizaeus-Merzbacher disease (PMD) caused by mutations in PLP1. Recently, homozygous mutations in GJA12 encoding connexin 47 were found in patients with autosomal-recessive Pelizaeus-Merzbacher-like disease (PMLD). However, many patients of both genders with PMLD carry neither PLP1 nor GJA12 mutations. We report a consanguineous Israeli Bedouin kindred with clinical and radiological findings compatible with PMLD, in which linkage to PLP1 and GJA12 was excluded. Using homozygosity mapping and mutation analysis, we have identified a homozygous missense mutation (D29G) not previously described in HSPD1, encoding the mitochondrial heat-shock protein 60 (Hsp60) in all affected individuals. The D29G mutation completely segregates with the disease-associated phenotype. The pathogenic effect of D29G on Hsp60-chaperonin activity was verified by an in vivo E. coli complementation assay, which demonstrated compromised ability of the D29G-Hsp60 mutant protein to support E. coli survival, especially at high temperatures. The disorder, which we have termed MitCHAP-60 disease, can be distinguished from spastic paraplegia 13 (SPG13), another Hsp60-associated autosomal-dominant neurodegenerative disorder, by its autosomal-recessive inheritance pattern, as well as by its early-onset, profound cerebral involvement and lethality. Our findings suggest that Hsp60 defects can cause neurodegenerative pathologies of varying severity, not previously suspected on the basis of the SPG13 phenotype. These findings should help to clarify the important role of Hsp60 in myelinogenesis and neurodegeneration.

Mutational analysis of the phage T4 morphogenetic 31 gene, whose product interacts with the Escherichia coli GroEL protein

The phage T4 morphogenetic gene 31 has been sequenced. Its deduced gene product is a polypeptide of 111 aa, with a predicted Mr of 12064 and a pI of 4.88. The proof that the assigned open reading frame (ORF) encodes Gp31 rests on the sequencing of two known gene 31 amber mutations, amN54 and NG71, demonstrating that these mutations result in translational termination within the assigned ORF. Furthermore, the sequencing of four different T4 epsilon mutations, isolated on the basis of allowing the phage to propagate on Escherichia coli groEL- hosts, showed that they are either missense mutations or 3-bp deletions in the gene 31 reading frame. The sequencing of neighboring DNA revealed the presence of five other ORFs, one of which overlaps gene 31 substantially, but in the opposite orientation.

Initiation of lambda DNA replication reconstituted with purified lambda and Escherichia coli replication proteins

Using highly purified bacteriophage lambda and E. coli replication proteins, we were able to reconstitute an in vitro system capable of replication ori lambda-containing plasmid DNA. The addition of a new E. coli factor, the grpE gene product, to this replication system reduced the level of dnaK protein required for efficient DNA synthesis by at least 10-fold, and also allowed the isolation of a stable DNA replication intermediate. Based on all available information, we propose a molecular mechanism for the action of the dnaK and grpE proteins during the prepriming reaction leading to lambda DNA synthesis.

An ORFan no more: the bacteriophage T4 39.2 gene product, NwgI, modulates GroEL chaperone function.

Bacteriophages are the most abundant biological entities in our biosphere, characterized by their hyperplasticity, mosaic composition, and the many unknown functions (ORFans) encoded by their immense genetic repertoire. These genes are potentially maintained by the bacteriophage to allow efficient propagation on hosts encountered in nature. To test this hypothesis, we devised a selection to identify bacteriophage-encoded gene(s) that modulate the host Escherichia coli GroEL/GroES chaperone machine, which is essential for the folding of certain host and bacteriophage proteins. As a result, we identified the bacteriophage RB69 gene 39.2, of previously unknown function and showed that homologs of 39.2 in bacteriophages T4, RB43, and RB49 similarly modulate GroEL/GroES. Production of wild-type bacteriophage T4 Gp39.2, a 58-amino-acid protein, (a) enables diverse bacteriophages to plaque on the otherwise nonpermissive groES or groEL mutant hosts in an allele-specific manner, (b) suppresses the temperature-sensitive phenotype of both groES and groEL mutants, (c) suppresses the defective UV-induced PolV function (UmuCD) of the groEL44 mutant, and (d) is lethal to the host when overproduced. Finally, as proof of principle that Gp39.2 is essential for bacteriophage growth on certain bacterial hosts, we constructed a T4 39.2 deletion strain and showed that, unlike the isogenic wild-type parent, it is incapable of propagating on certain groEL mutant hosts. We propose a model of how Gp39.2 modulates GroES/GroEL function.

Bacteriophage λ DNA Replication and the Role of the Universally Conserved dnaK, dnaJ and grpE Heat Shock Proteins

There are many similarities in the replication mechanisms employed by bacteriophage λ and its host E. coli (for reviews, see Bramhill and Kornberg, 1988, Keppel et al., 1988, and McMacken et al., 1987). In both cases, the host-coded primase enzyme (the dnaG gene product) is mostly responsible for synthesizing the RNA primers for both the leading and lagging strand, to be extended into DNA by the DNA polymerase III holoenzyme. A major problem in both systems is that the primase enzyme is normally unable to make RNA primers by itself (except in the case of a few single-stranded bacteriophages). Instead, it must first make contact with the dnaB helicase, properly positioned on single-stranded DNA. The dnaB helicase unwinds DNA by traveling in the 5’→3’ direction (LeBowitz and McMacken, 1986). To do so, the dnaB helicase must somehow “climb” onto DNA at a single-stranded region. Such a single-stranded DNA region is created at the E. coli oriC site by the binding of the dnaA•ATP protein form (Bramhill and Kornberg, 1988). To enter the single-stranded region at oriC, the dnaB helicase must be escorted by the dnaC initiation protein (Bramhill and Kornberg, 1988).