Gulnar Pothiawala scite author profile

Gulnar Pothiawala

4Publications

10Citation Statements Received

38Citation Statements Given

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Affiliations

Division of Parasitic Diseases and Malaria, National Institute of Allergy and Infectious Diseases

Publications

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Small numbers of residual tumor cells at the site of primary inoculation are critical for anti-tumor immunity following challenge at a secondary location

Kakinuma

Nadiminti

Lonsdorf

et al. 2006

Cancer Immunol Immunother

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Luciferase-transduced B16 murine melanoma cells (luc-B16) inoculated in ear skin do not form tumors but prevent tumor formation by luc-B16 cells injected into the footpad. To determine the requirements for such immunity, we followed the fate of luc-B16 cells following ear injection. Surprisingly, small numbers of viable luc-B16 cells were detected in tumor-free mouse skin for up to 60 days post-inoculation. After 1 week, the number of Foxp3(+)CD4(+)CD25(+) T cells (along with foxp3 mRNA expression) increased rapidly in the injected ear skin. Residual tumor cells in ears were reduced in mice treated with anti-CD25 mAb and in CD4-deficient mice, but increased in CD8-deficient mice. Strikingly, the loss of luc-B16 cells in the ear skin, either spontaneously or following amputation of the injected ear, resulted in significantly enhanced tumor formation by parental and luciferase-expressing B16 cells after footpad injection. These studies suggest that small numbers of tumor cells (possibly regulated by CD4(+)CD25(+) regulatory T cells expressing Foxp3) are required for effective host anti-tumor responses at alternate inoculation sites.

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Modifications and deletions of helices within the hairpin ribozyme–substrate complex: An active ribozyme lacking helix 1

Pinard

Lambert²,

Pothiawala³

et al. 2004

RNA

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Within the hairpin ribozyme, structural elements required for formation of the active tertiary structure are localized in two independently folding domains, each consisting of an internal loop flanked by helical elements. Here, we present results of a systematic examination of the relationship between the structure of the helical elements and the ability of the RNA to form the catalytically active tertiary structure. Deletions and mutational analyses indicate that helix 1 (H1) in domain A can be entirely eliminated, while segments of helices 2, 3, and 4 can also be deleted. From these results, we derive a new active minimal ribozyme that contains three helical elements, an internal loop, and a terminal loop. A three-dimensional model of this truncated ribozyme was generated using MC-SYM, and confirms that the catalytic core of the minimized construct can adopt a tertiary structure that is very similar to that of the nontruncated version. A new strategy is described to study the functional importance of various residues and chemical groups and to identify specific interdomain interactions. This approach uses two physically separated and truncated domains derived from the minimal motif.

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Ulcerated Facial Nodules in a Renal Transplant Recipient—Quiz Case

Hartford

Pothiawala²,

Goldman³

2010

Arch Dermatol

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Basic dermatology in children and adolescents

Casey¹,

Pothiawala²,

Gehris³

2008

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