Hans-Richard Rackwitz

Adipophilin is a specific marker of lipid accumulation in diverse cell types and diseases

Abstract We report the human DNA and protein sequence of adipophilin and its association with the surface of lipid droplets. The amino acid sequence of human adipophilin has been determined by using cDNA clones from several tissues and confirmed by the reverse transcription/polymerase chain reaction method and Edman sequencing. The open reading frame of adipophilin encodes a polypeptide with a calculated molecular weight of 48.1 kDa and an isoelectric point of 6.72. By immunofluorescence and electron-microscopic localization with newly raised specific poly- and monoclonal antibodies, we show that this protein is not restricted to adipocytes as previously indicated by studies of the mouse homologous protein, adipose-differentiation-related protein. Adipophilin occurs in a wide range of cultured cell lines, including fibroblasts and endothelial and epithelial cells. In tissues, however, expression of adipophilin is restricted to certain cell types, such as lactating mammary epithelial cells, adrenal cortex cells, Sertoli and Leydig cells of the male reproductive system, and steatosis or fatty change hepatocytes in alcoholic liver cirrhosis. Our results reveal adipophilin as a possible new marker for the identification of specialized differentiated cells containing lipid droplets and for diseases associated with fat-accumulating cells.

ETHER LIPID BIOSYNTHESIS : ISOLATION AND MOLECULAR CHARACTERIZATION OF HUMAN DIHYDROXYACETONEPHOSPHATE ACYLTRANSFERASE

In this paper we describe isolation and molecular characterization of human dihydroxyacetonephosphate acyltransferase (DAP‐AT). The enzyme was extracted from rabbit Harderian gland peroxisomes and isolated as a trimeric complex by sucrose density gradient centrifugation. From peptide sequences matching EST‐clones were obtained which allowed cloning and sequencing of the cDNA from a human cDNA library. The nucleotide‐derived amino acid sequence revealed a protein consisting of 680 amino acid residues of molecular mass 77 187 containing a C‐terminal type 1 peroxisomal targeting signal. Monospecific antibodies raised against this polypeptide efficiently immunoprecipitated DAP‐AT activity from solubilized peroxisomal preparations, thus demonstrating that the cloned cDNA codes for DAP‐AT.

Caspases target only two architectural components within the core structure of the nuclear pore complex.

Caspases were recently implicated in the functional impairment of the nuclear pore complex during apoptosis, affecting its dual activity as nucleocytoplasmic transport channel and permeability barrier. Concurrently, electron microscopic data indicated that nuclear pore morphology is not overtly altered in apoptotic cells, raising the question of how caspases may deactivate nuclear pore function while leaving its overall structure largely intact. To clarify this issue we have analyzed the fate of all known nuclear pore proteins during apoptotic cell death. Our results show that only two of more than 20 nuclear pore core structure components, namely Nup93 and Nup96, are caspase targets. Both proteins are cleaved near their N terminus, disrupting the domains required for interaction with other nucleoporins actively involved in transport and providing the permeability barrier but dispensable for maintaining the nuclear pore scaffold. Caspase-mediated proteolysis of only few nuclear pore complex components may exemplify a general strategy of apoptotic cells to efficiently disable huge macromolecular machines.

Nuclear coactivator protein p100 is present in endoplasmic reticulum and lipid droplets of milk secreting cells

We have identified the p100 protein, previously known as a novel cellular coactivator, as a constituent of endoplasmic reticulum and cytosolic lipid droplets from milk secreting cells. Cytosolic lipid droplets of terminally differentiated mammary epithelial cells are secreted as milk lipid globules. However, milk lipid globules did not have detectable amounts of p100 protein. The p100 protein was found also in cytosol from lactating mammary gland, in storage lipid droplets from mouse adipocytes, and in endoplasmic reticulum from liver. Immunofluorescence microscopy of mammary epithelial cells confirmed the presence of p100 in non-nuclear regions of these cells. Partial sequence analysis of tryptic peptides from p100 from cow mammary gland showed extensive homology with the reported sequence of p100 determined from a human cDNA. Antibodies against a peptide synthesized to duplicate a sequence in human p100 recognized a protein of the size of p100 in cow, mouse and rat cell fractions.

Characterization of Peptide Substrates and Viral Enzyme that Affect the Cleavage Site Specificity of the Human Spumaretrovirus Proteinase

Oligopeptides that correspond to proteolytic cleavage site junctions of the native Gag and Pol proteins are specifically cleaved by retroviral aspartate proteases (PRs). The role of the flap subdomain of the PR of the human spumaretrovirus (HSRV) and of substrate peptides in cleavage site specificity was analyzed by site-directed mutagenesis. Native and mutant peptides were subjected to proteolysis by the authentic and mutated recombinant viral enzyme. The results reveal that Glu residue 54 of the HSRV PR is an essential specificity determinant for proteolytic processing of the structural proteins. Peptides that represent in vivo cleavage sites were susceptible to proteolysis by the recombinant HSRV PR, but one peptide located at the junction between the PR and reverse transcriptase domains was completely resistant to cleavage. Thus the data indicate that a proteolytic cleavage between these domains does not occur in vivo. Naturally occurring and mutant forms of the cleavage-resistant peptide were therefore analyzed by circular dichroism to determine if differences existed in the secondary structures of the peptides that did or did not serve as substrates. The data show that differences in the secondary structure of the native and mutant peptides analyzed does not seem to play a crucial role for cleavage site specificity in HSRV PR. Instead highly conserved hydrophobic residues at distinct positions of the HSRV cleavage site junctions contribute to the specificity observed as reported for HIV-1 PR.