Fly colours

[overmywaders]

Hi Mike,

I'll take your presentations in order:

The newest studies indicate that adult trout can not perceive UV light. Also, even assuming these are wrong and trout can in fact perceive UV light ( although it would be better to call it "radiation", in my opinion, I think "light" is a rather unfortunate term in this respect), you need special equipment to detect UV radiation and you would have to test the natural flies you want to imitate under varying conditions of UV light, AND match what you found using artificials under the same circumstances. Even if possible this is difficult.

Well, only one "scientist" has stated in recent years that trout permanently lose their UV cones; the rest, including the recognized authority on the subject - Dr. Craig Hawryshyn state that the dorsal temporal region of the retina retains UV cones. See "Beaudet et al 1997 ; Deutschlander et al 2001; Allison et al 2006; Raine and Hawryshyn 2009; Raine et al in press. Note that at smoltification, the dorsotemporal field is retained and is functional. This is a observation that runs through all of our publications."

As for the single holdout, Dr. Inigo Flamarique, he stated in an email to me, after re-affirming his belief that the cones sensitive optimally to UV light are lost in smoltification:

DOES THIS MEAN THAT THE TROUT THAT IS A SMOLT AND OLDER DOES NOT SEE UV LIGHT? NO, EVERY VISUAL PIGMENT ABSORBS IN THE UV REGION OF THE SPECTRUM BUT ITS PEAK ABSORBANCE MAY NOT BE IN THE UV REGION OF THE SPECTRUM (SEE TYPICAL CURVES IN CHENG ET AL. 2006. J COMP NEUROL). BECAUSE THE LENS OF SALMONID FISHES TRANSMITS WAVELENGTHS IN THE RANGE 320-800 NM, ANY WAVELENGTH IN THE UV (320-400 NM) WILL BE SENSED BY THE BLUE, GREEN AND RED VISUAL PIGMENTS, ALBEIT THE SENSITIVITY OF THESE PIGMENTS TO UV PHOTONS WILL BE LESS THAN THAT OF A UV VISUAL PIGMENT. SO THE OVERALL SENSITIVITY OF THE SMOLT TO UV LIGHT (<400 NM) DECREASES DRAMATICALLY BUT IT DOES NOT MEAN THAT THE ANIMAL CANNOT SEE UV LIGHT. THE MAIN SENSORS OF THE UV LIGHT WILL NOW BE THE BLUE CONES (WHICH HAVE THE PEAK ABSORBANCE-LAMBDA MAX- NEAR THE UV PART OF THE SPECTRUM).

[Emphasis his]

You said:

you need special equipment to detect UV radiation and you would have to test the natural flies you want to imitate under varying conditions of UV light, AND match what you found using artificials under the same circumstances. Even if possible this is difficult.

So, that is what I did. I took what may have been the first UV reflectance photos of some mayfly species (and caddis, terrestrials, etc.) and took UV reflectance photos of the "Best dry fly patterns of 1984" as determined by Dave Whitlock. It was remarkable, and I was quick to remark upon it, that the artificials had the appropriate UV reflectance.

You said:

Also, in low light conditions, when fish primarily feed, there is very little UV light at all, if any. At such times you can not even measure any appreciable effects on various things, much less flies. So even assuming that the fish can see UV light, they can't see it if it is not there. Again a dead end.

Ah, not so. Actually, the 320-400nm wavelengths (UVA) diminish more slowly, percentage-wise, than visible light at dusk. As well, both moonlight and starlight provide UV. Since UV wavelengths penetrate water deeper than visible light, they create the ambient light underwater against which objects lower in UV reflectivity stand out.

Think about this - most mayflies perform their mating at night. Since this is their one and only chance for a "good time" it behooves them to find a mate of the proper species and sex. Most insects have UV vision, and mayflies have species and sex specific UV markings; just perfect for those lanquid moonlit nights above the river. : )

So, if mayflies have these UV markings, and trout can see in the UV, won't trout choose those flies that conform to the UV markings they expect?

My book, which is on Amazon, contains all those arguments, backed by proper citations. I'm not plugging it, Mike, but OTOH, I don't want to write it all again in this post.

Best regards,
Reed

[Mike Connor]

That's fair enough. As long as you accept one study over another. Of course you are perfectly entitled to do so. See also;

Cheng, C. L. & Flamarique, I. N. (2007). Chromatic organization of cone photoreceptors in the retina of rainbow trout: single cones irreversibly switch from UV (SWS1) to blue (SWS2) light sensitive opsin during natural development. Journal of Experimental Biology, 210, 4123-4135.

FULl PDF http://jeb.biologists.org/content/210/2 ... l.pdf+html

Cheng, et al. (2009). Thyroid hormone induces a time-dependent opsin switch in the retina of Salmonid fishes. Investigative Ophthalmology and Vision Science, 50, 3024-3032.

FULL PDF http://www.iovs.org/content/50/6/3024.full.pdf

With regard to the amount of UV light at dusk etc. Using this;

http://www.aegis-elec.com/products/sonyXCD-SX910UV.html ( borrowed from a friend at a local university and sadly no longer available), I was unable to find any insects at all in UV light ranges leading up to twilight in overcast conditions. This only went to ~380 nm. Doubtless there are better detectors but I have no access to them.

Agreed that insects can see into the UV ranges.

With regard to the reflectance itself, I found that the maximum UV reflectance coincided with the maximum "normal" reflectance. That is to say, a subject that reflected a lot of "normal" light also reflected a lot of UV if it was present. Polished metal and some other things were particularly noticeable.

Insects may have these UV markings but I tend towards the idea that the wing interference patterns are more important. They are species and sex specific and visible in any light against a dark background. Why would the insects develop two separate systems? It may be that the wing interference pattens are also visible in UV. I don't know, I have not tried that. One would need very sensitive detectors.

For the most part good imitations dressed according to human perceptions catch fish. There are a lot of patterns that prove this.

How would you go about designing an imitation based on the UV reflectance of the natural? Even if possible, then very difficult.

I can appreciate you not wanting to publish a lot of your book on here or a lot of what you write in it.

Thanks very much for coming along and discussing it at all.

TL
MC

[overmywaders]

Hi Mike,

It is not that I don't want to publish a lot of my book, it is that the matter of 'splainin' takes a lot of time.
You are making a lot of assumptions. But first, let us agree on terminology. When I am saying UV reflectance, I mean UV diffuse reflectance. We see most objects by diffuse reflection: "Reflection from a rough surface in which a collimated beam emerges in all directions." When we talk about shiny, mirror like reflectance, that is specular reflection: "sharply defined beam resulting from reflection off a smooth surface."

You said:

With regard to the reflectance itself, I found that the maximum UV reflectance coincided with the maximum "normal" reflectance. That is to say, a subject that reflected a lot of "normal" light also reflected a lot of UV if it was present. Polished metal and some other things were particularly noticeable.

So very untrue. Unless you have a camera with a sensor (or film) that can record in the UV, and a UV bandpass filter that transmits only UV wavelengths, you cannot see UV reflection. I have taken white winged marabou streamers from two different tiers. Both flies looked equally white in visible light, but in UV, one was bright, the other dark. [Most white paint looks dark in UV because TiO2 is added to absorb the UV and prevent paint degradation.] Watch the video on the homepage of my website - http://uvrdefensetech.com/index.php?home. If you go to gallery, you will see many more instances.

Below are two images of the same Black-eyed Susans. The first I took in visible light, the second in UV.




Bees and other pollinating insects use UV "targets" as markers.

As for metals, aluminum is equally reflective in UV and visible light; however, silver plummets once it crosses the 400nm threshold into UV - it reflects little UV light. Just check the spectral curve. The same with ZnO and TiO2 - Zinc oxide and Titanium oxide.

For convenience sake, I will plug my book. Jim will have some copies for sale, I guess, and it is also at http://www.amazon.com/New-Scientific-An ... 984086307/

Best regards,
Reed

[Mike Connor]

Hi Mike,

It is not that I don't want to publish a lot of my book, it is that the matter of 'splainin' takes a lot of time.
You are making a lot of assumptions. But first, let us agree on terminology. When I am saying UV reflectance, I mean UV diffuse reflectance. We see most objects by diffuse reflection: "Reflection from a rough surface in which a collimated beam emerges in all directions." When we talk about shiny, mirror like reflectance, that is specular reflection: "sharply defined beam resulting from reflection off a smooth surface."

You said:

With regard to the reflectance itself, I found that the maximum UV reflectance coincided with the maximum "normal" reflectance. That is to say, a subject that reflected a lot of "normal" light also reflected a lot of UV if it was present. Polished metal and some other things were particularly noticeable.

So very untrue. Unless you have a camera with a sensor (or film) that can record in the UV, and a UV bandpass filter that transmits only UV wavelengths, you cannot see UV reflection. I have taken white winged marabou streamers from two different tiers. Both flies looked equally white in visible light, but in UV, one was bright, the other dark. [Most white paint looks dark in UV because TiO2 is added to absorb the UV and prevent paint degradation.] Watch the video on the homepage of my website - http://uvrdefensetech.com/index.php?home. If you go to gallery, you will see many more instances.

Below are two images of the same Black-eyed Susans. The first I took in visible light, the second in UV.




Bees and other pollinating insects use UV "targets" as markers.

As for metals, aluminum is equally reflective in UV and visible light; however, silver plummets once it crosses the 400nm threshold into UV - it reflects little UV light. Just check the spectral curve. The same with ZnO and TiO2 - Zinc oxide and Titanium oxide.

For convenience sake, I will plug my book. Jim will have some copies for sale, I guess, and it is also at http://www.amazon.com/New-Scientific-An ... 984086307/

Best regards,
Reed

Well, I actually try very hard indeed not to assume anything at all! But as you quite rightly say, "'splainin' takes a lot of time" and effort, and in that regard one is often bound to assume certain things, one of which is that parameters are either known or agreed upon. This is extremely difficult I know.

I used various cameras and systems borrowed from a local university. Far too much data was collected to list here and doubtless a lot of it would be boring and irrelevant for most.

I meant diffuse reflectance.

The fact that insects use these things as markers, especially bees for instance, is well known and documented. What is very interesting in that regard is that bees and other insects become active at various times which coincide with normal daylight and become quiescent in low light. Birds which also see UV and use it for various things are also only active in daylight.

With regard to the "percentages". This can be extremely misleading. Assume UV portion =8% of daylight. Assume full daylight to be 100

Assume reduction of daylight to 10% of normal= 10. Assume that the UV portion is still 8% that is 8% of TEN, not 8% of 100 so the absolute level of UV is very considerably lower than in full daylight.

I wont plug anything!

TL
MC

[Mike Connor]

Just something else which occurred to me, and which I may have already mentioned in this thread, is my general disagreement with assigning "levels of priority" or "relative importance" to certain things. These are invariably entirely subjective, and usually worthless, because the failure or non-existence of any particular factor in many things will cause the whole thing to fail.

To illustrate this, one often hears "What do you think is most important, stealth, good flies, presentation, etc" or what do you think is the "order of importance". There is no sensible answer to questions like that because success depends on all these factors, and if one is missing then what you are trying to do will fail or at least not be optimum.

This is another point which is relevant to this discussion. Assuming that these UV factors play a part in the design, selection, and use of artificial flies. It can not be a major or essential part, or all the flies which have been designed and work extremely well to date, without these factors being known, either work independently of these theories, are coincidentally in accord with these theories, or the theories are wrong or irrelevant.

TL
MC

[overmywaders]

Hi Mike,

Okay, we have the term reflectance in common. However, what I can't understand is that when you did an investigation of UV with a multitude of cameras, you came to the conclusion that:

With regard to the reflectance itself, I found that the maximum UV reflectance coincided with the maximum "normal" reflectance. That is to say, a subject that reflected a lot of "normal" light also reflected a lot of UV if it was present. Polished metal and some other things were particularly noticeable.

The first dozen images you took should have contradicted that. I showed you the yellow flowers to indicate that "a subject that reflected a lot of "normal" light also reflected a lot of UV if it was present" is clearly not true. The yellow appears to be the same over the whole flower; yet some of it is dark in the UV.

Further, your investigation of polished metals should have shown the different reflectance in UV and visible. I'm surprised that when you had looked into the subject, you missed this old list of white pigments which is almost a mainstay:


All of the pigments are white in visible light but vary tremendously in UV. (There are other tables showing the spectral curve every ten nm in UV, if you need them.)

You said:

What is very interesting in that regard is that bees and other insects become active at various times which coincide with normal daylight and become quiescent in low light. Birds which also see UV and use it for various things are also only active in daylight.

I mentioned mayflies. The hatch often occurs by day, but the mating is very often at night, depending on the species and location. For example, the Hex hatch (mating) always occurs at night on the Manistee in MI. Many times mayflies mistake the UV character of roads near streams to be the streams themselves; hence icky windshields.

As for other animals, some species of microbats use UV vision at night.

For bats, the UV-sensitive cones may be advantageous for visual orientation at twilight, predator avoidance, and detection of UV-reflecting flowers for those that feed on nectar.

Bat Eyes Have Ultraviolet-Sensitive Cone Photoreceptors
Müller B, Glösmann M, Peichl L, Knop GC, Hagemann
C, et al. 2009
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2712075/

You said:

Assume reduction of daylight to 10% of normal= 10. Assume that the UV portion is still 8% that is 8% of TEN, not 8% of 100 so the absolute level of UV is very considerably lower than in full daylight.

That is funny. The actual scenario is that due to the wavelengths and energies, the higher-energy, shorter-wavelength UV light doesn't diminish at the same rate as the visible light. So,

“Interestingly, ambient light at dawn and dusk contains a particularly high proportion of short wavelengths.”

see bat article above
Also,

“The second experiment investigated more specifically whether UV cues are especially important in dawn and dusk when short wavelengths are high in
the proportion of available light.”
Do house mice use UV cues when foraging?
Johanna Honkavaara, Helena Åberg and Jussi Viitala
Journal of Ethology
Volume 26, Number 3 / September, 2008

Best regards,
Reed

[Mike Connor]

We can discuss this for a very long time with lots of references and studies, without actually getting anywhere. I don't want to get into contradicting or refuting things, it tends to go around in circles, So I will "cut to the chase", as it were.

Name or describe three flies that catch more fish as a result of some UV related factor known to you and for which you have evidence.

Name or describe one fly which has been designed using such factors that is successful. Preferably one that is MORE successful than another without these factors being taken into consideration and used in the same circumstances.

That was it really.

Those by the way are the same questions I ask people who tell me about the "positive triggers" they use. To date, nobody has even given me an answer.

TL
MC

[overmywaders]

First, Mike, why don't you address the issues I raised? That would seem fair. Then I will happily give you the examples you desire.

It would seem that your assertions were clearly refuted with citations or photos. You may wish to rebut with the same, or admit a new understanding. That keeps the discussion interesting, intellectually honest, and equitable. We are all learners here, I hope.

Best regards,
Reed

[Mike Connor]

First, Mike, why don't you address the issues I raised? That would seem fair. Then I will happily give you the examples you desire.

It would seem that your assertions were clearly refuted with citations or photos. You may wish to rebut with the same, or admit a new understanding. That keeps the discussion interesting, intellectually honest, and equitable. We are all learners here, I hope.

Best regards,
Reed

Because they are not relevant. I don't fish for bats, yellow flowers, or anything other than fish. These things may of course be used to buttress or support various ideas or theories and I have no objections at all to that. However, interesting as these things may be, they are not my primary concern here. I don't wish to rebut anything, or embark on long circular discussions. It merely confuses the issue. All I would like to know is how UV factors may be relevant to the flies I design and use.

If you can not or will not answer that, then there is no further point in discussion.

TL
MC

[Jim Slattery]

I would like to thank Reed Curry for joining the discussion, as well as everyone else who has participated. This has been a great thread, very enlightening and one of the reasons that makes this forum great. Open and honest discussions . I would think we have torn apart and dissected the uv subject quite well. There are a lot of good points sprinkled in the thread that will help in fly design and fishing , in turn perhaps some discovery on why some flies are more effective than others, even when tied "the same".
Jim