[Federal Register Volume 76, Number 92 (Thursday, May 12, 2011)]
[Notices]
[Pages 27653-27655]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2011-11668]
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DEPARTMENT OF HEALTH AND HUMAN SERVICES
National Institutes of Health
Office of Biotechnology Activities; Recombinant DNA Research:
Action Under the NIH Guidelines for Research Involving Recombinant DNA
Molecules (NIH Guidelines)
AGENCY: National Institutes of Health (NIH), PHS, DHHS.
ACTION: Notice of final actions under the NIH Guidelines and notice of
an addition to Appendix D of the NIH Guidelines.
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SUMMARY: A proposal to certify Kluyveromyces lactis as a host-vector 1
system has been reviewed by the NIH
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Recombinant DNA Advisory Committee (RAC) and approved by the NIH
Director. This decision is based upon the determination that the K.
lactis host-vector 1 system affords a moderate degree of biological
containment equal to other certified host-vector 1 systems presently
listed in the NIH Guidelines.
Moreover, it has been determined that certain research with this
host-vector system does not present a significant risk to health and
the environment and therefore will be exempt from the NIH Guidelines
(See Section III-F-6 and Appendix C). Appendix C has been modified to
indicate the nature of the research that is exempt when performed in a
K. lactis certified host-vector 1 system.
In addition, the Office of Biotechnology Activities is updating
Appendix D of the NIH Guidelines to include additional lines of
experimentation approved by the NIH Director; in this case an
experiment involving the introduction of tetracycline resistance into
Chlamydia trachomatis that falls under Section III-A-1-a of the NIH
Guidelines.
DATES: The final action regarding certification of a new host-vector 1
system is effective April 14, 2011.
FOR FURTHER INFORMATION CONTACT: Background documentation and
additional information can be obtained from the Office of Biotechnology
Activities, National Institutes of Health, 6705 Rockledge Drive, Suite
750, MSC 7985, Bethesda, Maryland 20892; e-mail at [email protected], or
telephone at 301-496-9838. The NIH OBA Web site is located at: http://oba.od.nih.gov/oba/.
SUPPLEMENTARY INORMATION: Under the NIH Guidelines, certification of a
host-vector 1 system is based on assessment of the biological
containment provided by the recombinant DNA vector (plasmid or virus)
and the host (bacterial or lower eukaryote) in which the vector is
propagated in the laboratory. Per the NIH Guidelines, a combination of
vector and host can be certified based on the ability of this system to
provide biological containment so that ``the following types of
`escape' are minimized: (i) Survival of the vector in its host outside
of the laboratory and (ii) transmission of the vector from the
propagation host to other non-laboratory hosts'' (see Appendix I-I).
Host-vector 1 systems provide a moderate level of containment (Appendix
I). Most low volume (< 10 liters) research with host-vector 1 systems
is exempt from the NIH Guidelines and therefore does not require
registration with the IBC. High volume (> than 10 liters) research with
a certified host-vector 1 system requires IBC review; however, the
required containment practices are not as comprehensive as those
required for similar research not involving a host-vector 1 system. For
example, because of the biological containment provided by the host-
vector 1 system, large volume research in a host-vector 1 system does
not require all recombinant material to be handled in a closed system.
In making a determination regarding whether a host-vector
combination provides moderate biological containment and therefore can
appropriately be certified as a host-vector 1 system, the following
information is considered: the host's natural habitat and growth
requirements; its physiologic properties, particularly reproduction,
survival, and mechanisms for exchange of genetic information; and the
history of the particular strains and vectors to be used, including
mutations that render this organism less able to survive or transmit
genetic information.
The Office of Biotechnology Activities received a request from New
England BioLabs (NEB) to certify K. lactis as a host-vector 1 system
under the NIH Guidelines and to exempt certain research with this host-
vector system. Specifically, NEB requested certification of two
parental, laboratory-adapted lineages of K. lactis. One is a strain
selected by the K. lactis research community for genome sequencing and
the second is a K. lactis strain originally isolated in the 1980s from
a dairy process. This latter strain has been used as a host strain in
the food industry for heterologous protein expression. In addition, NEB
has created host strains that are genetically modified through deletion
of one or more genes, including genes involved in the synthesis of
cellular components (e.g., those involved in biosynthetic activities
and modification of host proteins: proteases and glycosylases). Most of
the vectors proposed by NEB are plasmids derived from pGBN1, a K.
lactis-Escherichia coli shuttle plasmid containing selectable markers
for growth in both organisms. The pGBN1-derived plasmids stably
integrate into the LAC4 region of the K. lactis chromosome. Other
available plasmids for use in K. lactis are derived from the
Saccharomyces cerevisiae 2-micron plasmid and remain stable in an
episomal state with a copy number of about 50.
NEB noted that K. lactis has a 20+ year history of safe use as an
expression system in regulated food industry processes. NEB further
stated that they had found K. lactis to provide an excellent system for
heterologous protein expression. With regards to its appropriateness
for certification as a host-vector 1 system, K. lactis is closely
related to S. cerevisiae, which is certified as a host-vector 1 system.
K. lactis, however, is unable to exchange genetic material with this
closely related yeast. K. lactis can exchange genetic material only
with itself and in rare cases with other Kluyveromyces species, thus
affording an additional degree of biologic containment.
On November 15, 2010, background information on these actions and
instructions for submitting public comment were published in the
Federal Register (75 FR 69687). No public comments were received
regarding the proposal to certify K. lactis as a host-vector 1 system.
On December 7, 2010, the RAC discussed whether there are sufficient
data as outlined in Appendix I-II-B-1 of the NIH Guidelines to certify
K. lactis and its associated plasmids as a host-vector 1 system.
In its assessment of the request, the RAC considered a number of
factors, including that: (1) K. lactis is a natural and indispensable
component of cultured dairy processes (including yogurt, cheese and
buttermilk) and has been used widely in the food industry to express
heterologous proteins (e.g. lactase which has been used to treat
lactose intolerance); (2) its optimum growth is at 30 [deg]C, thereby
limiting its survival within humans and most other warm-blooded
animals; (3) genetic exchange is limited to a few Kluyveromyces
species, which rarely cause any disease in humans (with the exception
of rare reports of superficial skin disease with K. marxianus, a
closely related yeast), and (4) there are no documented cases of
disease or toxicity attributed to K. lactis. With regard to the
plasmids proposed for certification, the Committee noted that plasmids
that can replicate in K. lactis exist in low copy number, will not be
efficiently transferred between K. lactis strains, and are not
transferrable to other yeast via mating (K. lactis is unable to mate
with other yeast). In sum, it was determined that K. lactis meets the
requirements of a host-vector 1 system.
The RAC recommended that laboratory-adapted strains of K. lactis
should be certified as a host-vector 1 system, as it was the
Committee's assessment that laboratory adapted strains grown under
optimized laboratory conditions will be at a selective disadvantage,
and thus less competitive compared to strains isolated from the wild.
Of note, even wild-type K. lactis has a limited natural habitat and
growth requirement, mainly
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restricted to lactose-rich environments. Plasmids that can be used in
K. lactis are not capable of replicating to high copy numbers. Due to
the additional containment and corresponding vastly reduced risk to
either human health or the environment afforded by host-vector 1
systems, research with this system will be exempt from the NIH
Guidelines unless the system is: (i) Capable of producing a molecule
that is toxic to vertebrates; (ii) contains DNA from a Risk Group 3 or
4 organism (see Appendix B of the NIH Guidelines); or (iii) will be
employed for large scale (> 10 liters) experimentation.
The following new appendix (C-IV) will be added to Appendix C of
the NIH Guidelines. The current Appendices C-IV through C-VIII (and
sub-appendices) will be renumbered to Appendices C-V through C-IX,
respectively.
Appendix C-IV Kluyveromyces Host-Vector Systems
Experiments involving Kluyveromyces lactis host-vector systems,
with the exception of experiments listed in Appendix C-IV-A, are exempt
from the NIH Guidelines provided laboratory-adapted strains are used
(i.e. strains that have been adapted to growth under optimal or defined
laboratory conditions). For these exempt experiments, BL1 physical
containment is recommended. For large-scale fermentation experiments,
the appropriate physical containment conditions need be no greater than
those for the host organism unmodified by recombinant DNA techniques;
the Institutional Biosafety Committee may specify higher containment if
deemed necessary.
Appendix C-IV-A Exceptions
The following categories are not exempt from the NIH Guidelines:
(i) Experiments described in Section III-B, which require NIH/OBA and
Institutional Biosafety Committee approval before initiation; (ii)
experiments involving DNA from Risk Groups 3, 4, or restricted
organisms (see Appendix B, Classification of Human Etiologic Agents on
the Basis of Hazard, and Sections V-G and V-L, Footnotes and References
of Sections I through IV) or cells known to be infected with these
agents may be conducted under containment conditions specified in
Section III-D-2 with prior Institutional Biosafety Committee review and
approval; (iii) large-scale experiments (e.g., more than 10 liters of
culture), and (v) experiments involving the deliberate cloning of genes
coding for the biosynthesis of molecules toxic for vertebrates (see
Appendix F, Containment Conditions for Cloning of Genes Coding for the
Biosynthesis of Molecules Toxic for Vertebrates).
Additions to Appendix D of the NIH Guidelines
In accordance with Section III-A of the NIH Guidelines, Appendix D
of the NIH Guidelines will be modified as follows to reflect a recent
approval for the transfer of a drug resistance trait to a
microorganism.
Appendix D-118. Dr. Harlan Caldwell at the Rocky Mountain
Laboratories may conduct experiments to deliberately introduce a gene
encoding tetracycline resistance into Chlamydia trachomatis serovar L2.
This approval is specific to Dr. Caldwell and research with this
resistant organism may only occur under the conditions as specified by
the NIH Director. This approval was effective as of April 26, 2010.
Dated: May 6, 2011.
Jacqueline Corrigan-Curay,
Acting Director, Office of Biotechnology Activities, National
Institutes of Health.
[FR Doc. 2011-11668 Filed 5-11-11; 8:45 am]
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