Katherine A. Sacksteder

Discovery and development of SQ109: a new antitubercular drug with a novel mechanism of action

Existing drugs have limited efficacy against the rising threat of drug-resistant TB, have significant side effects, and must be given in combinations of four to six drugs for at least 6 months for drug-sensitive TB and up to 24 months for drug-resistant TB. The long treatment duration has led to increased patient noncompliance with therapy. This, in turn, drives the development of additional drug resistance in a spiral that has resulted in some forms of TB being currently untreatable by existing drugs. New antitubercular drugs in development, particularly those with mechanisms of action that are different from existing first- and second-line TB drugs, are anticipated to be effective against both drug-sensitive and drug-resistant TB. SQ109 is a new TB drug candidate with a novel mechanism of action that was safe and well tolerated in Phase I and early Phase II clinical trials. We describe herein the identification, development and characterization of SQ109 as a promising new antitubercular drug.

Identification of the α-Aminoadipic Semialdehyde Synthase Gene, Which Is Defective in Familial Hyperlysinemia

The first two steps in the mammalian lysine-degradation pathway are catalyzed by lysine-ketoglutarate reductase and saccharopine dehydrogenase, respectively, resulting in the conversion of lysine to alpha-aminoadipic semialdehyde. Defects in one or both of these activities result in familial hyperlysinemia, an autosomal recessive condition characterized by hyperlysinemia, lysinuria, and variable saccharopinuria. In yeast, lysine-ketoglutarate reductase and saccharopine dehydrogenase are encoded by the LYS1 and LYS9 genes, respectively, and we searched the available sequence databases for their human homologues. We identified a single cDNA that encoded an apparently bifunctional protein, with the N-terminal half similar to that of yeast LYS1 and with the C-terminal half similar to that of yeast LYS9. This bifunctional protein has previously been referred to as alpha-aminoadipic semialdehyde synthase, and we have tentatively designated this gene AASS. The AASS cDNA contains an open reading frame of 2,781 bp predicted to encode a 927-amino-acid-long protein. The gene has been sequenced and contains 24 exons scattered over 68 kb and maps to chromosome 7q31.3. Northern blot analysis revealed the presence of several transcripts in all tissues examined, with the highest expression occurring in the liver. We sequenced the genomic DNA from a single patient with hyperlysinemia (JJa). The patient is the product of a consanguineous mating and is homozygous for an out-of-frame 9-bp deletion in exon 15, which results in a premature stop codon at position 534 of the protein. On the basis of these and other results, we propose that AASS catalyzes the first two steps of the major lysine-degradation pathway in human cells and that inactivating mutations in the AASS gene are a cause of hyperlysinemia.

Discovery of dipiperidines as new antitubercular agents

As part of our ongoing research effort to develop new therapeutics for treatment of tuberculosis (TB), we synthesized a combinatorial library of 10,358 compounds on solid support using a pool-and-split technique and tested the resulting compounds for activity against Mycobacteriumtuberculosis. Structure-activity relationship (SAR) evaluation identified new compounds with antitubercular activity, including a novel hit series that is structurally unrelated to any existing antitubercular drugs, dipiperidines. Dipiperidine representatives exhibited MIC values as low as 7.8microM, the ability to induce promoter Rv0341 activated in response to cell wall biosynthesis inhibition, relatively low nonspecific cellular toxicity in the range of 30-162microM, and logP values less than 4.

Preclinical study of new TB drugs and drug combinations in mouse models.

Tuberculosis (TB) remains one of the leading infectious killers in the world. New anti-TB drugs and more effective drug combinations are urgently needed, particularly given the increasing incidence of drug-resistant TB and HIV-TB co-infection. This review describes the available mouse models of TB and describes their utility in the evaluation of new TB drug candidates and in the evaluation of the efficacy of new TB drug combinations. Some of the most recent patents on promising TB drug-candidates are also mentioned here.

New tuberculosis vaccine development

Tuberculosis (TB) is a devastating disease that kills more than three million people each year. Of these, 0.9 million are co-infected with HIV and numbers of infections and death continue to rise with the global spread of HIV. A new vaccine is desperately needed to control this epidemic that threatens to kill 90 million people over the next 3 decades. Outstanding work in research laboratories, combined with the success of genome sequencing, has resulted in a variety of candidate TB vaccines, many of which are sufficiently promising to advance into clinical trials. This review discusses the array of new candidate TB vaccines and the clinical studies that are currently planned.

Generation of a Novel Nucleic Acid-Based Reporter System To Detect Phenotypic Susceptibility to Antibiotics in Mycobacterium tuberculosis

ABSTRACT We designed, constructed, and evaluated a prototype novel reporter system comprised of two functional cassettes: (i) the SP6 RNA polymerase gene under transcriptional control of a promoter active in mycobacteria and (ii) the consensus SP6 polymerase promoter that directs expression of an otherwise unexpressed sequence. We incorporated the reporter system into a mycobacteriophage for delivery into viable Mycobacterium tuberculosis, and introduction led to synthesis of an SP6 polymerase-dependent surrogate marker RNA that we detected by reverse transcriptase PCR (RT-PCR). The reporter confirmed the susceptibility profile of both drug-susceptible and drug-resistant M. tuberculosis strains exposed to first-line antitubercular drugs and required as little as 16 h of exposure to antibacterial agents targeting bacterial metabolic processes to accurately read the reaction. The reporter system translated the bacterial phenotype into a language interpretable by rapid and sensitive nucleic acid detection. As a phenotypic assay that works only on viable M. tuberculosis, it could be used to rapidly assess resistance to any drug, including drugs for which the mechanism of resistance is unknown or which result from many potential known (and unknown) genetic alterations. IMPORTANCE The ability to detect antibiotic resistance of slow-growing bacteria (i.e., Mycobacterium tuberculosis) is hampered by two factors, the time to detection (weeks to months) and the resistance mechanism (unknown for many drugs), delaying the appropriate treatment of patients with drug-resistant or multidrug-resistant tuberculosis (TB). The novel technique described in this article uses a unique surrogate nucleic acid marker produced by phage that infects M. tuberculosis to record phenotypic antibiotic susceptibility in less than a day. The ability to detect antibiotic resistance of slow-growing bacteria (i.e., Mycobacterium tuberculosis) is hampered by two factors, the time to detection (weeks to months) and the resistance mechanism (unknown for many drugs), delaying the appropriate treatment of patients with drug-resistant or multidrug-resistant tuberculosis (TB). The novel technique described in this article uses a unique surrogate nucleic acid marker produced by phage that infects M. tuberculosis to record phenotypic antibiotic susceptibility in less than a day.