Cloning and Biochemical Characterization of the Hectochlorin Biosynthetic Gene Cluster from the Marine Cyanobacteriumlyngbya Majuscula

Cloning and Biochemical Characterization of the Hectochlorin Biosynthetic Gene Cluster from the Marine Cyanobacteriumlyngbya Majuscula

AN ABSTRACT OF THE DISSERTATION OF Aishwarya V. Ramaswamy for the degree of Doctor of Philosophy in Microbiology presented on June 02, 2005. Title: Cloning and Biochemical Characterization of the Hectochiorin Biosynthetic Gene Cluster from the Marine Cyanobacterium Lyngbya maluscula Abstract approved: Redacted for privacy William H. Gerwick Cyanobacteria are rich in biologically active secondary metabolites, many of which have potential application as anticancer or antimicrobial drugs or as useful probes in cell biology studies. A Jamaican isolate of the marine cyanobacterium, Lyngbya majuscula was the source of a novel antifungal and cytotoxic secondary metabolite, hectochlorin. The structure of hectochiorin suggested that it was derived from a hybid PKS/NIRPS system. Unique features of hectochlorin such as the presence of a gem dichloro functionality and two 2,3-dihydroxy isovaleric acid prompted efforts to clone and characterize the gene cluster involved in hectochiorin biosynthesis. Initial attempts to isolate the hectochlorin biosynthetic gene cluster led to the identification of a mixed PKS/NRPS gene cluster, LMcryl,whose genetic architecture did not substantiate its involvement in the biosynthesis of hectochlorin. This gene cluster was designated as a cryptic gene cluster because a corresponding metabolite remains as yet unidentified. The expression of thisgene cluster was successfully demonstrated using RT-PCR and these results form the basis for characterizing the metabolite using a novel interdisciplinary approach. A 38 kb region putatively involved in the biosynthesis of hectochiorin has also been isolated and characterized. The hct gene cluster consists of eightopen reading frames (ORFs) and appears to be colinear with regard to hectoclilorin biosynthesis. An unusual feature of this gene cluster includes the presence ofa ketoreductase domain in an NRPS module and appears to be the first report of suchan occurrence in a cyanobacterial secondary metabolite gene cluster Other tailoring enzymes present in the gene cluster are two cytochrome P450 monooxygenases anda putative halogenase. The juxtaposition of two ORF's with identical modular organization suggests that this gene cluster may have resulted from a gene duplication event. Furthermore, biochemical characterization of two adenylation domains from this cluster strengthens its involvement in the biosynthesis of hectochiorin. ©Copyright by Aishwarya V. Ramaswamy June 02, 2005 All Rights Reserved Cloning and Biochemical Characterization of the Hectochiorin Biosynthetic Gene Cluster from the Marine CyanobacteriumLyngbya majuscula by Aishwarya V. Ramaswamy A DISSERTATION submitted to Oregon State University in partial fulfillment of the requirements for the degree of Doctor of Philosophy Presented June 02, 2005 Commencement June 2006 Doctor of Philosophy dissertation of Aishwarya V. Ramaswamy presented on June 02, 2005. APPROVED: Redacted for privacy Maj or Professor, representing Microbiology Redacted for privacy Chair of the Department of Microbiology Redacted for privacy Dean of the GiIaduè School I understand that my dissertation will become part of the permanent collection of Oregon State University libraries. My signature below authorizes the release of my dissertation to any reader upon request. Redacted for privacy shwarya V. Ramaswamy, Author ACKNOWLEDGEMENTS I would like to express my sincere gratitude to my major professor, Dr. William H. Gerwick, for his remarkable support and guidance throughout the course of my graduate work. I would also like to thank my committee members, Dr. Mark Zabriskie, Dr. Steve Giovannoni, Dr. George Constantine and Dr. Jeff Stone for their assistance. 11 am very grateful to Dr. Patricia Flatt and Dr. Daniel Edwards for their mentorship and invaluable guidance throughout my graduate career. I would like to acknowledge Dr. Kerry McPhail, Dr. Harald Gross and Dr. Lena Gerwick for their academic guidance. I would also like to thank Gloria Zeller for her help and friendship. Special thanks also go to former and current members of the Gerwick group for their friendship. Most importantly, I share this accomplishment with my parents and am deeply indebted to them for their love, constant encouragement, unconditional support and confidence in my abilities. Finally, I thank my husband for his love and patience which helped me immensely during these challenging years. TABLE OF CONTENTS CHAPTER I: GENERAL INTRODUCTION......................................... 1 GENERAL THESIS CONTENTS........................................... 38 REFERENCES..................................................................39 CHAPTER II: ISOLATION OF A CRYPTIC GENE CLUSTER FROM THE CYANOBACTERIUM LYNGBYA MAJUSCULA JHB AND DEMONSTRATION OF ITS EXPRESSION INTRODUCTION............................................................. 54 RESULTS AND DISCUSSION.............................................. 57 EXPERIMENTAL.............................................................. 85 REFERENCES................................................................. 92 CHAPTER III: CLONING AND BIOCHEMICAL CHARACTERIZATION OF THE HECTOCHLOR1N BIOSYNTHETIC GENE CLUSTER FROM THE MARINE CYANOBACTERIUM LYNGBYA MAJUSCULA INTRODUCTION.............................................................. 99 RESULTS AND DISCUSSION............................................. 102 EXPERIMENTAL............................................................. 126 REFERENCES...................................................................... 132 TABLE OF CONTENTS (Continued) CHAPTER IV: EXPRESSION AND BIOCHEMICAL CHARACTERIZATION OF ADENYLATION DOMAINS FROM THE CARMABIN BIOSYNTHETIC GENE CLUSTER INTRODUCTION................................................................................ 138 RESULTS AND DISCUSSION........................................................... 143 EXPERIMENTAL............................................................................... 148 REFERENCES..................................................................................... 150 CHAPTER V: CONCLUSIONS.......................................................................... 153 BIBLIOGRAPHY................................................................................................ 156 LIST OF FIGURES Figure Page 1.1 NRPS module organization...............................................................20 1.2 Recognition of cognate amino acid by binding pocket residues (A) and activation of amino acid by the NIRPS A-domain (B)......................................................................................................21 1.3 Post-translational modification of the PCP domain..........................22 1.4 Loading of PCP domain with activated amino acid..........................22 1.5 Condensation domains catalyze peptide bond formation..................23 1.6 Steps involved in nonribosomal peptide biosynthesis.......................24 1.7 Reactions catalyzed by NRPS tailoring domains..............................25 1.8 PKS module organization..................................................................28 1.9 Recognition of substrate by the AT domain and its transfer to ACP domain.....................................................................29 1.10 Ketide bond formation catalyzed by the KS domain........................ 29 1.11 Reactions catalyzed by PKS auxiliary domains................................30 1.12 The barbamide (53) biosynthetic gene cluster..................................35 LIST OF FIGURES (Continued) Figure 1.13 The curacin A (14) biosynthetic gene cluster....................................35 1.14 The jamaicamide A (27) biosynthetic gene cluster...........................36 1.15 The lyngbyatoxin A (30) biosynthetic gene cluster..........................36 ILl Isolation of high molecular weight genomic DNA...........................58 11.2 Proposed biosynthetic precursors of hectochiorin............................60 11.3 Amplification of NRPS A-domain probes........................................62 11.4 ClustalW alignment of cysteine adenylation domains......................63 11.5 Amplification of cyteine-specific A-domain.....................................64 11.6 Amplification of KS domain probe...................................................65 11.7 Restriction digest analyses (A) and Southern hybridizations of cosmids 1-105 and 111-105 (B)...........................................................67 11.8 Genetic architecture of LMcryland modular organization of LMcryl ..............................................................................................70 11.9 Alignment of heterocyclization domains.......................................... 71 LIST OF FIGURES (Continued) Figure 11.10 Alignment of N-methyl transferases.................................................73 11.11 Nonribosomal peptides from freshwater and terrestrial cyanobacteria.....................................................................................73 11.12 Sequence alignments of PKS domains of LMcryl with other cyanobacterial PKS's........................................................................ 75 11.13 Structure of proposed peptide encoded by hybrid NRPS/PKS encoded byLMciyl.R = unknown side chain..................................76 11.14 Reversed phase HPLC profiles for the crude extract and nine normal phase VLC fractions (A-I) of the cultured Lyngbya majusculaJHB..................................................................................79 11.15 Schematic

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