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. 2016 Mar 23;67(8):2121–2123. doi: 10.1093/jxb/erw113

Fuel for the road – sugar transport and pollen tube growth

Anke Reinders 1,
PMCID: PMC4809301  PMID: 27022182

Pollen tubes require the activity of carbohydrate uptake transporters to sustain their high growth rate. The work of Rottmann and colleagues in this issue (pages 2387–2399) provides evidence that expression of a hexose transporter in pollen tubes may be regulated via the hexokinase signaling pathway.

Pollen, the male gametophyte (haploid generation) of flowering plants, is responsible for delivering sperm cells to the egg sac, a process essential for sexual reproduction. Interaction between pollen and stigma (pollination) initiates secretion in the stigma and pollen germination. The pollen tube emerges and grows through the style to the ovaries where it delivers the sperm cells to the ovule to accomplish fertilization (Box 1) (Edlund et al., 2004). In Arabidopsis, the male gametophyte consists of three cells – one vegetative cell that encloses two sperm cells. Despite this seemingly simple system, about half of all Arabidopsis genes are expressed in pollen (Bock et al., 2006). There has been much recent progress in the field of pollen biology, especially in the area of pollen tube guidance and reception by the female gametophyte (reviewed by Kanaoka and Higashiyama, 2015).

Pollen tubes have been studied intensively as a model system for tip growth, a process vital in diverse cell types from fungal hyphae to cancer cells (Sanati and Geitmann, 2013). Basic research on pollen biology also has many direct practical applications. The vast majority of the world’s harvest depends upon successful plant reproduction. In many crop plants the male gametophyte is sensitive to environmental stress, such as heat and drought, which can lead to serious crop losses (Zinn et al., 2010). Understanding pollen function is therefore also of important practical interest.

Carbohydrate uptake into pollen tubes

Pollen tubes can sustain very rapid growth rates (5.3 µm min–1 in Arabidopsis; Wilhelmi and Preuss, 1996) and achieve lengths of 25cm or more in maize. Carbohydrates and other storage compounds stored in mature pollen are sufficient to support pollen survival and germination but pollen tubes use carbohydrate secretions from the stylar canal to support growth (Labarca and Loewus, 1973). Since the pollen tube is symplastically isolated from the surrounding tissue of the style and transmitting tract, the activity of membrane transporters is required in order to import nutrients from the sporophyte tissue to contribute to cell wall synthesis and respiration of the growing pollen tube. It is therefore interesting to note that genes encoding membrane transporters are overrepresented in the pollen transcriptome (Bock et al., 2006). Pollen can germinate in vitro in relatively simple media, which made the first pollen transcriptome studies possible. More recent work using a semi-in vivo method where pollen is applied to a stigma, after which the style is cut – allowing the pollen tubes to grow out onto the medium – showed that certain genes are specifically induced after growth through the pistil tissue (Qin et al., 2009). Interestingly, there are not many examples of sugar transporters for which a function in pollen has been demonstrated. One example is the Arabidopsis sucrose transporter AtSUC1, which can be localized to the plasma membrane in pollen tubes. Loss of function affects pollen germination in vitro and causes segregation distortion in vivo (Sivitz et al., 2008).

However, pollen tubes also express a cell wall-localized invertase (Singh and Knox, 1984) and are capable of hydrolysing all of the sucrose in germination media to fructose and glucose (Ylstra et al., 1998). It is not known to what extent pollen tubes take up sucrose compared to its hydrolysis products fructose and glucose. There are a large number of hexose transporters expressed in pollen and direct evidence for their involvement in pollen function has probably been hampered by redundancy. In Arabidopsis there are 14 members of the SUGAR TRANSPORT PROTEIN (STP) family alone, and six of them are expressed in pollen (reviewed in Büttner, 2010; Rottmann et al., 2016). STP2, STP4, STP6, STP9 and STP11 are expressed at different stages of pollen development. STP4, STP10 and STP11 are expressed in pollen tubes and may be necessary for the uptake of hexoses from the surrounding tissue. Even though all evidence points to a role for STPs in pollen, no pollen-related loss-of-function phenotype has been described for any of the STPs.

Glucose repression of STP10 via hexokinase 1

The paper by Rottmann et al. (2016) describes the characterization of Arabidopsis STP10. Two aspects are especially interesting for understanding the role of STPs in pollen: evidence for possible hexokinase-dependent repression of expression and for expression pattern regulation by intragenic domains. Expression of STP10 in yeast was used to show that it encodes a hexose transporter with high affinity for glucose. STP10 also transports galactose and mannose, but not fructose. While no impairment of pollen function was found in an stp10 loss-of-function mutant, possibly due to redundancy, Rottmann et al. provide intriguing insight into the regulation of STP expression in pollen. STP10 is highly induced during pollen germination, both in vitro and even more in semi-in vivo pollen tubes (Qin et al., 2009; Rottmann et al., 2016). The authors show that expression is only detectable after pollen germination and that the protein is localized to the pollen tube plasma membrane. Induction was lost during in vitro germination of pollen when 50mM glucose was added to the medium; fructose and mannose did not have this effect, nor did adding 50mM glucose and 50mM fructose at the same time. Expression of STP4, another pollen tube-expressed hexose transporter, was affected in the same way. The downregulation of expression of STP10 and STP4 no longer occurred in two independent hexokinase 1 mutants. Hexokinase 1 has a dual role, both as a glucose sensor and as an enzyme that converts glucose to glucose-6-phosphate (Sheen, 2014). The findings by Rottmann et al. suggest that the glucose signal that leads to the decrease in STP10 and STP4 expression may be transmitted via the hexokinase pathway.

Box 1. Pollen tube growth

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The images show pollen tubes growing through the ovary to reach the egg cells in wild-type Arabidopsis (above, scale bar = 50 µm; aniline blue staining) and stp10-1 pollen tubes in vitro (below, scale bar = 100 µm). Courtesy of Dr Ruth Stadler.

More information is available concerning transcriptional control of STP10. In a triple myb97 myb101 myb120 mutant, the pollen tubes fail to burst upon reaching the synergid and therefore do not deliver the sperm to the ovule. Interestingly, in this mutant a number of genes are no longer induced during pollen germination, among them STP10 (Leydon et al., 2013). STP10 may therefore be a direct or indirect target of MYB regulation. The three MYBs themselves are induced during growth through the pistil tissue.

An additional interesting finding by Rottmann et al. (2016) is that intragenic regions of STP10 seem to be involved in providing specificity to the expression of STP10. A promoter–GUS fusion showed expression in many more tissues than a whole-gene–GUS fusion, indicating that a transcriptional repressor may be present in intron, exon or UTR sequences.

Next steps for understanding sugar uptake by pollen

Future work will undoubtedly have to address the issue of redundancy, and the creation and analysis of double or higher-order multiple mutants in several hexose/sugar transporter genes. We also need to know what sugars are available in the transmitting tract, especially in Arabidopsis. Such data would provide a realistic picture of the conditions encountered by growing pollen tubes and help us understand how they get the nutrition necessary for rapid growth.

References

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