One of the
modern dilemmas in tomato production and breeding relates to managing
post-harvest losses associated with the modern agricultural practice of
concentrated fruit production in one area and fruit consumption in another
place (and time). Ripe fruit is easy to
damage in transit and deteriorates relatively quickly. Picking mature green (MG) fruit for shipment
and gassing with ethylene at a distant delivery point to “ripen” the fruit
solved the problem of damage in shipping, but comes with an unfortunate
sacrifice in flavor. As an alternative
to this practice plant biologists and tomato breeders have looked at various
genetic variants (mutations) in genes controlling the ripening process, and
examined how these novel alleles might be deployed in the development of
varieties with great flavor and enhanced shelf life. In this post I’ve tried to summarize the
current understanding of this field and share some of our related breeding
efforts.
Tomato Fruit Development (from Alba et al., 2005)
The
Ripening Process
Tomatoes are
a climacteric fruit, which means that the plant hormone ethylene is required
for fruit ripening. Ethylene is rapidly
produced in tomato fruit at the breaker (BK) stage and drives a series of
reactions that together define the fruit ripening process. During normal ripening there are simultaneous
and independent processes that lead to 1) accumulation of sugars, organic acids
and volatile organic compounds influencing flavor, 2) conversion of
chloroplasts to chromoplasts and the synthesis and accumulation of carotenoid
pigments and 3) softening of the fruit.
In a perfect modern tomato, ripening steps 1&2 proceed normally and
step 3 proceeds at slow rate – allowing the tomato fruit to keep peak flavor,
color and texture for an extended period of time.
ESL, or extended shelf life, is a term
describing a collection of traits that together extend the potential time
between picking of fully ripe or nearly fully ripe fruit, and the deterioration
of fruit quality. Fruit quality
deterioration is usually associated with fruit softness/undesirable texture and
fruit rotting. Taste panels have
identified fruit texture as an important determinant in consumer preference,
and soft or mealy fruit is a major “turn-off”.
Deterioration in fruit firmness/texture is generally associated with a
ripening related spike in polygalacturonase (PG) and other enzymes that degrade
fruit cell wall polysaccharides. Thus, a decline in fruit firmness typically
coincides with dissolution of the middle lamella and hemicellulosic/pectic cell
wall polysaccharides, thereby undermining the polysaccharide network that hold
cells together in the fruit pericarp. FlavrSavr
tomato, the commercially unsuccessful GE trait introduced by Calgene in 1985,
was designed to specifically suppress PG activity in ripening tomatoes. Recent research has also implicated cuticle
composition and architecture as traits influencing ripening-induced fruit
softening (Saladie et al. 2007 and Kosma et al. 2010). The cuticle has long been implicated as a
contributor to fruit strength, and cuticle structure changes during the
ripening process. Kosma et al, show that
during the ripening process ESL mutants generally have cuticles with mechanical
properties significantly different than the wild type – likely contributing to
ESL per se.
It should be noted that independent of
the several novel mutant alleles described below, there are significant
genetic differences in firmness in tomatoes.
Unfortunately there are a couple of studies that report fruit firmness
at harvest is not well correlated with the maintenance of fruit firmness
postharvest. We have found that pericarp
thickness, relative to size of the locules, is a heritable trait that significantly
impacts firmness per se, and appears in many cases to be associated with
improved shelf life (see photos below).
This combination of traits is common in many newer commercial hybrids.
Firm when ripe phenotype |
There are several mutations in key structural or regulatory tomato genes that affect the ripening process. These genes generally either inhibit ethylene synthesis and/or modify ethylene’s downstream effects on specific biochemical processes related to fruit ripening. To better understand climacteric fruit ripening per se, and to examine the potential utilization of these mutant alleles for delayed ripening/extended shelf life – tomato scientists have characterized several mutant alleles associated with a delayed ripening phenotype. Several key ripening mutants are described in detail below.
Key
genetic mutations affecting tomato fruit ripening
rin =
ripening inhibitor. The RIN gene
is a transcription factor that acts as a master regulatory gene controlling
numerous genes and pathways associated with tomato fruit ripening. The rin loss of function mutant is a
recessive allele that both represses genes associated with ethylene synthesis
and modifies downstream processes associated with the normal ripening
process. Specifically rin modifies
expression of other transcription factors associated with fruit ripening (e.g.
NOR); prevents normal fruit pigmentation by suppressing synthesis of Phytoene
synthase (PSY), the primary enzyme regulating flux into the carotenoid pathway
(see Genetic Control of Fruit Color in Tomatoes);
suppresses key steps in the accumulation of sugars, organic acids and aromatic
compounds associated the improved flavor in ripe tomato fruit; suppress enzymes
(e.g. polygalacturonase = “PG”) associated with breakdown of cell wall
polysaccharides that lead to ripening-related fruit softening; and modifies
cutin and fruit wax content and composition.
The rin/rin homozygote plant
produces fruit that never fully ripen and have much firmer fruit with a
significantly longer shelf life (see photo below). The lack of normal color and flavor
significantly limits commercial potential of rin/rin plants. In the heterozygous condition rin/+ plants
produce fruit with near normal fruit color and flavor, and shelf life that is
intermediate between rin/rin and +/+ (wild type) plants. F1 hybrids with the
rin/+ genotype and extended shelf life have been widely commercialized and are
a key driver in the recent availability of “vine ripened” tomatoes in grocery
stores. The extended shelf life allows
picking at or near the full ripe stage when flavor is near peak, and remaining
firm for an extended period of time for shipping to distant locations.
We have been
developing and testing new rin/rin inbreds and rin/+ hybrids for the last few
years.
Although rin/rin lines generally
have very low fruit sugars, there are differences in sugar levels between
rin/rin lines. The sweetest rin/rin
lines generally produce the sweetest rin/+ hybrids, though this is also heavily
influenced by the non-rin parent in the hybrid.
Lycopene levels in rin/+ hybrids is a little lower than wild type
(orange/red vs dark red), but normal red color can be restored in ogc/ogc crimson
types (e.g. Mountain Magic). Enhanced
shelf life in rin/+ hybrids appears to be influenced by rin per se, but also on
the genetic background of the rin and wild type parents, specifically those
genes influencing fruit firmness. Ripening
is a little slower with rin/+ hybrids, adding perhaps 5-7 days. We are making great progress on rin/+ hybrids
and it appears possible to combine a significant improvement in shelf-life with
exceptional flavor in fruit in a wide range of colors, shapes and sizes.
Striped rin/rin cherry |
Wild Type rin/rin nor/nor
Photo by Martel, 2010
nor =
non-ripening. The NOR gene is an
unrelated transcription factor that also serves as a master regulator of fruit
ripening in tomato. The recessive loss
of function mutant allele nor has been widely studied. The nor/nor homozygote has a very similar
phenotype to rin/rin, and nor/+ hybrids also have much restored color and
flavor with extended shelf-life – though reports in the literature suggest less
color and flavor and longer shelf life in nor/+ relative to rin/+. The specific mechanisms for modification of
ripening in nor mutants is less understood than with rin – but like RIN, NOR
helps regulate multiple genes and pathways important in tomato fruit
ripening. Commercial nor/+ hybrids have
been commercially successful, though probably less so than rin/+. Note that the next few mutants described
here, alc and dfd, are thought to be allelic to nor (i.e. independent NOR
mutants) with subtle but significant differences in ESL phenotypes.
alc = alcobaca. The Spanish tomato landraces Alcobaca, Penjar and Tomàtiga de
Ramellet are
generally “long keeping” types with much delayed fruit deterioration. These landraces have been selected for
hundreds of years for local adaptation to a dry climate and for fruit that will
have acceptable quality for months after harvest. The photo below shows a typical fall/winter
storage strategy employed in the region – fruit are hung in small bunches for
medium term storage. Note the term tomatiga de penjar means tomato for
hanging. There is a single recessive allele
“alc” associated with the slow ripening phenotype. The alc allele is believed to be another
mutation at the NOR locus. Fruit from
alc/alc plants have significantly lower levels of endogenous ethylene,
suppressed polygalacturonase activity and firmer fruit. Fruit harvested at the onset of ripening
mature to an orange color, and those left on the plant until full ripening have
normal red color. The landraces listed
above are all alc/alc and can remain firm for several months, though there is
wide variation for this LSL trait within local populations – suggesting alc +
other factors are at play. The ESL trait
associated with alc also appears to be subject to the level of water stress
during fruit production – with generally enhanced ESL under more arid
production conditions. Hybrids that are
heterozygous for alc (alc/+) have shelf life intermediate between +/+ and
alc/alc, and may be another interesting candidate gene/allele for an extended shelf life tomato
Effect of alc on fruit deterioration |
dfd = delayed
fruit deterioration. The dfd trait was
first found in certain ecotypes growing in the southern Mediterranean. The literature suggests that dfd is a partially
dominant mutant allele of NOR, and may indeed by identical to or a slight
variation to alc. DFD controls cuticle
composition and leads to decreased cell water loss, increasing cell turgor
(firmness) per se, and decreasing fruit water loss generally during ripening. Normally as tomato fruit ripen the cuticle
weakens and grows less resistant to penetration. Fruit of dfd plants require significantly
more force for cuticle penetration than those from wild type varieties, and do
not exhibit a normal progressive weakening of the cuticle during ripening. Fruit from dfd plants exhibit the normal ripening-induced
fruit cell wall breakdown and cell separation typical of wild type, but show
substantial swelling of pericarp cells during the ripening that is atypical,
with a ~4x increase in cell size vs wild type in ripe fruit, likely related to
increased cell turgor. There is
also less fruit water loss in dfd vs wild type ripening fruit – another
contributing factor to improved fruit firmness.
Increased cell turgor, decreased fruit moisture loss and increased
cuticle strength all appear to be related to changes in cuticle wax content and
composition in dfd vs wild type.
Unlike rin,
and nor, dfd’s affect on fruit firmness/LSL was independent of normal fruit
coloration and ripening-related accumulation of sugars and organic acids. Futhermore dfd/dfd plants maintained firmer
fruit without impacting expression of genes, such a PG, involved in ripening
induced cell wall degradation (unlike alc).
The dfd mutant appears to represent a very novel approach for ESL that
may be used in combination with other ESL traits to enhance shelf life in
tomato hybrids or O.P. varieties.
Changes in Fruit Coloration after Breaker Stage
Fruit Shelf Life of Nine LSL Tomato Hybrids (Yogendra et al. 2013)
Nr =
never ripe and Gr=green ripe.
These are dominant, gain of function mutations at independent loci, that
each results in reduced ethylene responsiveness in tomato fruit tissue. The ethylene insensitivity in both Gr and Nr
have a negative impact on seed germination and seedling vigor and completely
prevent normal fruit ripening. Negative
plant and fruit phenotypes prevent any commercial use of these mutant alleles.
Summary
Although the
mutant alleles rin, nor and alc generate a somewhat similar ESL phenotype in
plants heterozygous for these alleles, rin and nor are independent loci and all three have
different modes of action. With all three alleles, extended shelf life is
associated with later maturity, and with rin and nor also associated with
decreased pigmentation (see photo above).
The mutant alleles of these three genes have a similar effect on
extending shelf life, and the maintenance of firmness is due both to the mutant
alleles per se, and the background genotype of both the male and female parents. We have found that a rin/+ genotype in a firm
fruited background can extend shelf life for over two weeks. In such a case a fruit picked fully ripe can
stay crisp and firm on the countertop (or in transit to local or distant
markets) for at least 14-21 days. Since
several of the key aromatic compounds impacting flavor are directly derived
from lycopene and other carotenoid pigments, in theory one might expect that
the lower carotenoid pigment content of rin/+ hybrids might lead to lower
flavor. However by selecting ruthlessly
for flavor in parent lines, we have been able to identify rin/rin parents that
contribute high flavor to rin/+ hybrids.
It is
currently unclear how closely related are the NOR mutants nor, alc and dfd. The dfd mutant is somewhat of a mystery, perhaps due to a Cornell
patent filing on a specific dfd sequence – in the patent they do describe this
as a NOR mutant derived from a Mediterranean ecotype. To complicate matters more a Davis, CA
company Arcadia has patented an induced mutation in NOR (reference), which they
claim to be an improvement on the naturally occurring nor loss of function
mutant. It is too early to know how
similar the Arcadia mutant might be to alc or dfd.
The primary
use of extended shelf life (ESL) tomato hybrids will likely be for medium/large
size grower (field or protected culture) producing for distant markets. Picking an ESL hybrid at or just before full
ripening (in the marketplace = vine ripened) then packing and shipping, can be
a consumer and taste-friendly alternative to the traditional “green and gassed”
model. We think ESL types will also be
well suited to smaller producers selling in more local markets. These types could be picked less frequently, and
once picked, be much less prone to post harvest losses. It appears there may be several different
gene/allele options for ESL, with varying efficacy, ease of use, and freedom to
operate. We think ESL will be an
increasing important trait for fresh market tomatoes, with perhaps evolving
breeding strategies for optimization of the trait. We will build on our early success with rin,
and continue to follow and explore the other options described here. Our multi-year effort in selecting for fruit
firmness and flavor per se is paying off – deployment of rin or one of the NOR
mutants will likely require a firm fruit background for optimization of ESL,
and a high flavor background will likely be needed to counter the delayed
ripening effect of rin/+, nor/+, or alc hybrids.
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