B
BESS T-Scan Method S e e
B A S E
E X C I S I O N
SEQUENCE SCANNING
 (
BESS
).
Best Linear Unbiased Prediction (BLUP)
A statistical (data) technique employed by
livestock breeders to determine the breeding
(genetic trait) value of animals in a breeding
program. See also 
GENETICS
,
TRAIT
,
PHENO-
TYPE
,
GENOTYPE
,
EXPECTED PROGENY DIFFER-
ENCES
 (
EPD
).
Beta Carotene A phytochemical (vitamin pre-
cursor) that is naturally produced in carrots,
other orange vegetables, and in the
endosperm portion of the corn (maize) ker-
nel. If the corn kernel seed coat is torn (e.g.,
via insect chewing), the beta carotene inhib-
its growth of Aspergillus flavus fungi in the
endosperm region of the kernel. In 1970, an
orange (-fruited) cauliflower was discovered
growing in a field in Canada. It was the result
of a natural mutation that caused beta caro-
tene to be produced in that cauliflower plant,
at a level that was several hundred times
higher than normal for cauliflower. Beta car-
otene has been found to aid eyesight in peo-
ple who consume it, and may help prevent
lung cancer and heart disease. Because beta
carotene is processed into vitamin A by the
human body, consumption of this phyto-
chemical can help avoid human diseases
(e.g., in developing countries where vitamin
A is scarce) that result from vitamin A defi-
ciency, e.g., coronary heart disease, certain
cancers (cancer of prostate, lungs, etc.),
childhood blindness, macular degeneration
(a leading cause of blindness in older peo-
ple), and various childhood diseases which
often result in death due to a weakened
immune system. See also 
VITAMIN
,
GOLDEN
RICE
,
AFLATOXIN
,
FUNGUS
,
OH
43
,
PHYTOCHEMI-
CALS
,
NUTRACEUTICALS
,
CAROTENOIDS
,
CANCER
,
CORONARY HEART DISEASE
  (
CHD
),
ANTIOXI-
DANTS
,
DESATURASE
.
Beta Cells Insulin-producing cells in the pan-
creas. If these cells are destroyed, childhood
(also known as early-onset or Type I) diabe-
tes results. See also 
ISLETS OF LANGERHANS
,
INSULIN
,
TYPE I DIABETES
.
Beta Conformation An extended, zigzag
arrangement of a polypeptide (molecule)
chain. See also 
POLYPEPTIDE
 (
PROTEIN
).
Beta Interferon One of the interferons, it is a
protein that was approved by the U.S. Food
and Drug Administration (FDA) in 1993 to
be used to treat multiple sclerosis (MS). See
also
INTERFERONS
,
FOOD AND DRUG ADMINISTRA-
TION
 (
FDA
),
PROTEIN
.
Beta Oxidation See
CARNITINE
.
Beta Sitostanol See
SITOSTANOL
.
Beta Sitosterol See
SITOSTEROL
.
Beta-conglycinin Abbreviated 
β-conglycinin.
One of the (structural) categories of proteins
produced in seeds of legumes. In general,
β-conglycinin contains one-quarter to one-
third as much cysteine (cys) and methionine
(met) per unit of protein as does glycinin.
β-conglycinin has greater emulsifying
capacity (in water) and emulsion stability
than does glycinin, so its presence can assist
the manufacture of firmer tofu, and better
protein-based (emulsion) drinks. See also
PROTEIN
,
CYSTEINE
  (
cys
),
METHIONINE
  (
met
),
GLYCININ
,
EMULSION
.
Beta-D-Glucouronidase See
GUS GENE
.
Beta-Glucan See
WATER SOLUBLE FIBER
.
Beta-lactam Antibiotics A category of antibi-
otics (e.g., penicillin G, ampicillin, etc.) that
kill targeted bacteria by altering their essen-
tial cellular function of enzymatic controls
that keep cell wall (peptido-glycan) synthe-
sis (creation/repair) in balance with cell wall
degradation. This causes cell wall breakdown
and death of those bacteria (pathogens). See
also
ANTIBIOTIC
,
PENICILLIN G
,
BACTERIA
,
CELL
,
ENZYME
,
PATHOGEN
,
bla
GENE
.
Beta-Secretase An enzyme that (in the human
brain) is linked to presence of Alzheimer’s
disease. See also 
ENZYME
,
ALZHEIMER
’
S DIS-
EASE
,
AMYLOID
β
PROTEIN PRECURSOR
 (
A
β
PP
).
BEVs See
BACULOVIRUS
,
BACULOVIRUS EXPRES-
SION VECTORS
 (
BEV
s
).
BFGF Basic Fibroblast Growth Factor. See
also
FIBROBLAST GROWTH FACTOR
 (
FGF
).
BGYF See
BRIGHT GREENISH
-
YELLOW FLUORES-
CENCE
 (
BGYF
).
Bifidobacteria See
BIFIDUS
.
Bifidus A “family” of bacteria species that
live within the digestive systems of certain
animals (humans, swine, etc.). Examples
include Bifidobacterium bifidum, Bifidobacte-
rium longum, Bifidobacterium infantis, Bifido-
bacterium adolescentis, and Bifidobacterium
© 2002 by CRC Press LLC

B
acidophilus. In general, Bifidus bacteria help
to promote good health of the host animals,
by several means.
They produce organic acids (e.g., propi-
onic, acetic, lactic), which make the host
animal’s digestive system more acidic.
Because most pathogens (disease-causing
microorganisms) grow best at a neutral pH
(neither acidic nor base/caustic), the growth
rates of pathogens are thereby inhibited.
They “crowd out” enteric pathogens, since
Bifidus bacteria grow fast in the acidic envi-
ronment created by those organic acids.
Some of the organic acids (e.g., propionic)
produced by Bifidus bacteria are able to pass
through the outer cell membrane of patho-
genic bacteria and fungi; once inside those
pathogens’ cells, these acids dissociate and
acidify the cell interior (which disrupts pro-
tein synthesis, growth, and replication of that
pathogen). They produce bacteriocins,
which are proteins that suppress growth of
the pathogenic bacteria. They produce cer-
tain short-chain fatty acids, which are
absorbed by the host animal (e.g., in the
colon) and thereby result in a reduction of
triglycerides (fat) levels in the host animal’s
bloodstream. That triglyceride reduction
lowers the risk of coronary heart disease and
thrombosis. See also 
BACTERIA
,
SPECIES
,
ACID
,
BASE
  (
GENERAL
),
PATHOGEN
,
CELL
,
PLASMA
MEMBRANE
,
MICROORGANISM
,
FUNGUS
,
PROTEIN
,
RIBOSOMES
,
GROWTH
  (
MICROBIAL
),
FRUCTOSE
OLIGOSACCHARIDES
,
FATTY ACID
,
TRIGLYCER-
IDES
,
CORONARY HEART DISEASE
 (
CHD
),
THROM-
BOSIS
,
PREBIOTICS
,
BACTERIOCINS
,
INSULIN
,
TRANSGALACTO
-
OLIGOSACCHARIDES
.
Bile A liquid (mixture) made by the liver to
help digest fats (in the intestine) and facili-
tate intestinal absorption of certain vitamins
and minerals. Bile consists primarily of
water, cholesterol, lipids (fat), “natural
detergents” (i.e., salts of bile acids) that help
break up fat globules in the intestines, and
bilirubin. See also 
BILE ACIDS
,
BILIRUBIN
,
FATS
,
DIGESTION
 (
WITHIN ORGANISMS
).
Bile Acids A “family” of acids derived by the
human liver from cholesterol (i.e., from
foods), and excreted into the bile by the liver.
They help to emulsify (food-source) fats in
the small intestine, as part of the crucial first
step in the digestion of fats. See also 
CHO-
LESTEROL
,
DIGESTION
 (
WITHIN ORGANISMS
),
LEC-
ITHIN
,
FATS
,
LIPIDS
.
Bilirubin A component (pigment) of red blood
cells (i.e., erythrocytes), that is recovered (from
old red blood cells) and recycled into making
bile (a liquid that aids the digestive process) by
the liver. See also 
ERYTHROCYTES
,
BILE
,
DIGES-
TION
 (
WITHIN ORGANISMS
),
ENDOTHELIUM
.
BIO See
BIOTECHNOLOGY INDUSTRY ORGANIZA-
TION
 (
BIO
).
Bioassay Determination of the relative
strength or bioactivity of a substance (e.g.,
a drug). A biological system (such as living
cells, organs, tissues, or whole animals) is
exposed to the substance in question and the
effect on the living test system is measured.
See also 
BIOLOGICAL ACTIVITY
,
ASSAY
,
BIOCHIP
.
Biochemistry The study of chemical pro-
cesses that comprise living things (systems);
the chemistry of life and living matter.
Despite the dramatic differences in the
appearances of living things, the basic chem-
istry of all organisms is strikingly similar.
Even tiny one-celled creatures carry out
essentially the same chemical reactions that
each cell of a complex organism (such as
man) carries out. See also 
MOLECULAR BIOL-
OGY
,
MOLECULAR DIVERSITY
.
Biochip A term first used with regard to an
electronic device that utilizes biological
molecules as the “framework” for other mol-
ecules acting as semiconductors and func-
tioning as an integrated circuit.
1. During the 1990s, this term also
became commonly used to refer to var-
ious “laboratories on a chip” to:
• Analyze very small samples of DNA
• Assess the impact of pharmaceuticals
— or pharmaceutical drug candidate
molecules — on specific cells (i.e.,
attached to the biochip’s surface) or
on specific cellular receptors
(ligand-receptor response of cell)
• Size and sort DNA fragments
(genes) via the (proportional) fluo-
rescence of dyes intercalated in the
DNA molecules
• Detect presence of specific DNA
fragments (genes) via hybridization
© 2002 by CRC Press LLC

B
to a probe (that was fabricated onto
the chip)
• Size and sort protein molecules (via
various cells fabricated onto the chip)
• Assess pharmaceuticals via adhe-
sion molecules attached to the chip
• Detect specific pathogens or cancer-
ous cells in a blood sample (e.g., by
applying controlled electrical fields
to cause those cells to collect at elec-
trodes on the chip)
• Screen for compounds that act
against a disease (e.g., by applying
antibodies linked to fluorescent mol-
ecules, then measuring electroni-
cally the fluorescence triggered by
antibody-binding)
• Conduct gene expression analysis by
measuring the fluorescence of mes-
senger RNA (specific to which par-
ticular gene is “turned on”) when
that mRNA hybridizes with DNA
(from genome) on hybridization sur-
face on the chip
2. Shortly after the 1990s, several com-
panies manufactured biochips capable
of sequencing (determining the
sequence of) DNA samples. Such bio-
chips have, attached to their surfaces,
all possible “DNA probes” (short
sequences of DNA). The sample (i.e.,
the unknown DNA molecule) is passed
over the probe-covered surface of the
biochip, where each relevant segment
(within the large unknown DNA mol-
ecule) hybridizes (“pairs”) with the
short “DNA probe” attached to a
known location on the surface of the
biochip. Because the sequence of each
DNA probe — at each specified loca-
tion on the biochip — is known, that
i n f o r m a t i o n   ( i . e . ,   t h e   p r o b e s ’
sequences to which the unknown DNA
molecule hybridized) is then used to
“assemble the complete sequence” of
the unknown DNA molecule.
3. Sometimes refers to an electronic
device that uses biological molecules as
the framework for other molecules that
act as semiconductors and function as an
integrated circuit. The future working
parts of the science of bioelectronics,
biochips may consist of two- or three-
dimensional arrays of organic mole-
cules used as switching or memory ele-
ments. If biochip technology proves to
be feasible, one application will be to
shrink currently existing biosensors in
size. This would enable the biosensors
to be implanted in the body or in organs
and tissues for the sake of monitoring
and controlling certain bodily func-
tions. A future possibility is to try to
provide sight for the blind using light-
sensitive (e.g., protein-covered elec-
trode) biochips implanted in the eyes to
replace a damaged retina. For example,
during 2001, Alan Chow implanted
such biochips into several men whose
retinas had been damaged by the dis-
ease retinitis pigmentosa.
See also 
BIOELECTRONICS
,
BIONICS
,
BIOSENSORS
(
ELECTRONIC
),
DEOXYRIBONUCLEIC ACID
  (
DNA
),
RIBONUCLEIC ACID
  (
RNA
),
GENE
,
RECEPTORS
,
HIGH
-
THROUGHPUT SCREENING
  (
HTS
),
BIOINOR-
GANIC
,
TARGET
-
LIGAND INTERACTION SCREENING
,
ANTIBODY
,
CHARACTERIZATION ASSAY
,
BIOASSAY
,
ASSAY
,
LUMINESCENT ASSAY
,
PROTEIN
,
LIGAND
(
IN BIOCHEMISTRY
),
MICROFLUIDICS
,
PROBE
,
PRO-
TEOMICS
,
PROTEOME CHIP
,
BIORECEPTORS
,
HYBRIDIZATION
  (
MOLECULAR BIOLOGY
),
FLUO-
RESCENCE
,
ADHESION MOLECULE
,
GENE EXPRES-
SION ANALYSIS
,
PATHOGEN
,
BIOINFORMATICS
,
MICROARRAY
  (
TESTING
),
HYBRIDIZATION SUR-
FACES
,
MESSENGER RNA
  (
m
RNA
),
GENOMICS
,
QUANTUM DOT
,
QUANTUM WIRE
,
NANOCOMPOS-
ITES
,
SEQUENCING
 (
OF DNA MOLECULES
).
Biocide Any chemical or chemical compound
that is toxic to living things (systems). Lit-
erally “biokiller” or killer of biological sys-
tems. Includes insecticides, bactericides,
fungicides, etc. Most bactericides accom-
plish their task (killing bacteria) via massive
lysis (disintegration) of bacteria cell walls
(membranes). However, one (triclosan) kills
bacteria by inhibiting enoyl-acyl protein
reductase; a crucial enzyme utilized by bac-
teria in their synthesis of fatty acids. See also
BACTERICIDE
,
MICROBICIDE
,
LYSIS
,
BACTERIA
,
CELL
,
FATTY ACID
,
ENZYME
,
PROTEIN
,
ESSENTIAL
FATTY ACIDS
,
ESSENTIAL NUTRIENTS
.
© 2002 by CRC Press LLC

B
Biodegradable Describes any material that
can be broken down by biological action
(dissimilation, digestion, denitrification,
etc.). The breakdown of material (e.g., ani-
mal carcasses, dead plants, even manmade
chemicals) by microorganisms (bacteria,
fungus, etc.). The biodegradation process is
often assisted (i.e., first step) by the actions
of animals and insects (e.g., feeding on dead
carcasses, which breaks down those car-
casses to make their materials more available
for microorganisms to “feed” upon). For
example, vultures and the yellow swallow-
tail butterfly often are the first to feed on the
carcasses of dead alligators in the state of
Florida, which helps make the alligator’s
material (body tissue) more readily available
to microorganisms (e.g., in the dung excreted
by those “first step” carcass feeders). See
also
DIGESTION
  (
WITHIN ORGANISMS
),
MICRO-
ORGANISMS
,
BACTERIA
,
FUNGUS
,
GLYCOLYSIS
,
METABOLISM
,
NITRIFICATION
.
Biodesulfurization The removal of organic
and inorganic sulfur (a pollution source)
from coal by bacterial and soil microorgan-
isms. See also 
BIOLEACHING
,
BIORECOVERY
,
BIOSORBENTS
.
Biodiversity Defined to be “the variability
among living organisms from all sources
including terrestrial, marine/aquatic and the
complexes of which they are a part” by the
Convention on Biological Diversity. See also
CONVENTION ON BIOLOGICAL DIVERSITY
.
Bioelectronics Also called biomolecular elec-
tronics. It is the field where biotechnology
is crossed with electronics. The branch of
biotechnology that deals with the electroac-
tive properties of biological materials, sys-
tems, and processes, together with their
exploitation in electronic devices. Bioelec-
tronics will attempt to replace traditional
semiconductor materials (e.g., silicon or gal-
lium arsenide) with organic materials such
as proteins (biochips). See also 
BIOCHIPS
,
BIO-
SENSORS
 (
ELECTRONIC
),
BIOINORGANIC
,
BIONICS
,
QUANTUM WIRE
,
SELF
-
ASSEMBLY
  (
OF A LARGE
MOLECULAR STRUCTURE
).
Biogenesis The theory that living organisms are
produced only by other living organisms. That
is, the theory of generation from preexisting
life. It is the opposite of abiogenesis, or
spontaneous generation.
Biogeochemistry A branch of geochemistry
that is concerned with biological materials
and their relation to earth’s chemicals in an
area.
Bioinformatics This term refers to the gener-
ation/creation, collection, storage (in data-
b a s e s ) ,   a n d   e ffi c i e n t   u t i l i z a t i o n   o f
data/information from genomics (functional
genomics, structural genomics, etc.), combi-
natorial chemistry, high-throughput screen-
ing, proteomics, and DNA sequencing
research efforts in order to accomplish a
(research) objective (e.g., to discover a new
pharmaceutical or a new herbicide). Exam-
ples of the data/information that are manipu-
lated and stored include gene sequences,
biological activity/function, pharmacologi-
cal activity, biological structure, molecular
structure, protein-protein interactions, and
gene expression products/amounts/timing.
See also 
GENOMICS
,
FUNCTIONAL GENOMICS
,
PHARMACOGENOMICS
,
STRUCTURAL GENOMICS
,
COMBINATORIAL CHEMISTRY
,
HIGH
-
THROUGHPUT
SCREENING
,
PROTEOMICS
,
BIOCHIP
,
GENE
,
GENETIC MAP
,
GENETIC CODE
,
SEQUENCING
  (
OF
DNA MOLECULES
),
IN SILICO BIOLOGY
,
IN SILICO
SCREENING
,
GENE EXPRESSION ANALYSIS
,
META-
MODEL METHODS
 (
OF BIOINFORMATICS
).
Bioinorganic This term refers to the combina-
tion of organic (life) materials with inorganic
materials to create (useful materials). For
example, Abalone shellfish make their shells
via a combination of protein and calcium
carbonate. Researchers are working on mak-
ing semiconductor devices (chips) containing
peptides, etc. attached to silicon or gallium
arsenide. See also 
PROTEIN
,
BIOCHIP
,
PEPTIDE
,
BIOSENSORS
 (
ELECTRONIC
),
NANOCOMPOSITES
.
Bioleaching The biomediated recovery of pre-
cious metals from their ores. In the recovery
of gold, for example, the microorganism
T. ferroxidans may be used to cause the gold
to leach out of the ore so it may then be
concentrated and smelted. Aluminum may
be similarly bioleached from clay ores, using
heterotropic bacteria and fungi. See also
BIORECOVERY
,
BIOGEOCHEMISTRY
,
BACTERIA
,
BIOSORBENTS
.
© 2002 by CRC Press LLC

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